gpoq4A0TScWNdIGcKsVo_Chapter 5 - Structure and Function of Systems.pdf

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5 – Structure and Function of Systems
5.1 Integumentary System

DERMAL LAYERS
Stratified squamous epithelial cells
Cells in the deepest epidermis are constantly dividing and being pushed
Epidermis
toward the surface
Dead cells leave behind keratin/phospholipids which waterproof the skin
-composed of loose connective tissue
Dermis
-contains blood vessels, nerve endings and exocrine glands
Hypodermis -contains adipose tissue for insulation

FUNCTIONS
1. Prevent Water Loss Important for homeostasis / osmoregulation
Heat Retention Heat Removal
Vasoconstriction (cutaneous) Vasodilation (cutaneous)
2. Thermoregulation
Hairs/arrector pilimotor muscles Sweat (osmoregulation)
Adipose tissue (hypodermis)
From pathogens
3. Physical Protection Fingernails / toenails (made of keratin) protect fingers / toes
Callus build up protects areas more prone to abrasion

Control
Cutaneous vasculature is innervated by the sympathetic branch of the ANS
Epinephrine results in cutaneous vasoconstriction and sweating

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5.2 Skeletal System
STRUCTURE/FUNCTION OF SKELETAL SYSTEM
1. Structural Rigidity and Support
2. Calcium Storage
Functions
3. Physical Protection
4. Hematopoiesis – red bone marrow synthesizes RBCs, WBCs, and platelets
Axial Skeleton Appendicular Skeleton
head and trunk All appendages
Skeletal skull (including pelvis and shoulder girdle)
Structure spinal column
sternum
ribcage
Flat Bones
Ex. pelvis, sternum, skull
Protect vital organs
Spongy bone surrounded by layer of compact bone
Contain red marrow (hematopoiesis)
Long Bones
Bone Arms and legs
Types Provide support and mobility
Epiphyses contain spongy bone (red marrow - hematopoiesis) surrounded by
a layer of compact bone.
Epiphyses are coated with articular cartilage.
Diaphysis (central shaft) is a tube of compact bone with yellow marrow and
blood vessels inside.
Epiphyseal plate is the site of bone growth in children / adolescents.

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 JOINTS
Synarthrosis Don’t allow movement (ex. Skull)
Amphiarthrosis Allow limited movement (ex. intervertebral disks)
Freely movable joint
1. Gliding – carpals of the wrist
Diarthrosis
2. Hinge – elbow
(Synovial)
3. Saddle - thumb
4. Ball and Socket – shoulders and hips

Arthritis – Inflammation of a joint (can lead to destruction of the articular cartilage)

BONE STRUCTURE
Extracellular tissue composed of a calcium phosphate
(hydroxyapatite) / collagen matrix
Produced by osteoblasts from calcified cartilage
Vascular and innervated
The osteon is the fundamental unit of compact bone.
Osteocyte – mature osteoblast trapped in lacunae in between layers of
lamellae in the osteon
Osteoclast – cells responsible for reabsorbing Ca2+ from bones

CARTILAGE
Extracellular tissue secreted by chondroblasts/chondrocytes
Composed of a collagen/elastin matrix with proteoglycans interspersed
Avascular and not innervated
Strong, flexible
Hyaline
Ex. nose, ears, trachea, ribs, synovial joints (articular cartilage)
Strong, rigid
Fibro
Ex. intervertebral disks
Strong, flexible
Elastic
Ex. ear lobes, epiglottis, larynx

LIGAMENTS AND TENDONS
Ligaments connective tissue connecting bone to bone
Tendons connective tissue connecting muscle to bone

HORMONAL REGULATION OF BONE GROWTH / REMODELING
Calcitriol (D3) Parathyroid Hormone (PTH) Calcitonin
Increases plasma [Ca2+] Increases plasma [Ca2+] Decreases plasma [Ca2+]
Secreted by the kidneys Secreted by the parathyroid Secreted by the thyroid
Stimulates osteoclasts Stimulates osteoclasts Inhibits osteoclasts
Increases renal reabsorption Increases renal reabsorption Increases renal secretion
Increases intestinal absorption Increases calcitriol

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5.3 Muscular System
FUNCTIONS OF THE MUSCULAR SYSTEM
1. Support and Mobility
2. Peripheral Circulatory Assistance
3. Thermoregulation (Shivering Reflex)
Simultaneous stimulation of antagonistic pairs of skeletal muscles by the SNS

MUSCLE TYPES
STRIATED (SKELETAL) CARDIAC SMOOTH

Striated (sarcomeres) Striated (sarcomeres) Not striated (no sarcomeres)
Voluntary Involuntary Involuntary
Skeletal system Heart Hollow organs, tubes, sphincters
Multi-nucleated Uni-nucleated Uni-nucleated
No gap junctions Gap junctions Gap junctions
Somatic motor neurons Autorhythmic cells Autonomic efferent neurons
Regulated by Ca2+ (SR) Regulated by Ca2+ (SR) Regulated by Ca2+ (extracellular/SR)
Troponin / tropomyosin Troponin / tropomyosin calmodulin / MLCK
Fastest contractions Intermediate contractions Slowest contractions

Muscle Structure and Control of Muscle Contraction
t-tubules – branched network of tubules that are continuous with the sarcolemma
Allows faster transmission of action potentials from cell surface to the interior of the fiber
The sarcoplasmic reticulum stores/sequesters Ca2+ needed for muscle contraction.
Red muscle cells (a.k.a. dark meat) contain abundant mitochondria and myoglobin.

MUSCLE CELL VOCABULARY
muscle fiber = muscle cell
sarcolemma = cell membrane
sarcoplasm = cytoplasm
sarcoplasmic reticulum (SR) = modified ER

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Regulation of Cardiac Muscle Contraction
An action potential (AP) is first produced by
autorhythmic cells in the SA node (SinoAtrial
node).
Contractions aren’t initiated by the nervous
system!
There is a delay in the transmission at the AV node.
The trasmission is spread throughout the atria and
ventricles via gap junctions.

Nervous System Control
Neurons may innervate many muscle fibers.
Muscle fibers are innervated by one neuron.
Acetylcholine is the neurotransmitter at neuromuscular
junctions.

Increased muscle tension is accomplished by:
1. Increased recruitment of motor units
2. Increased frequency of stimulation

ENERGY CONSUMPTION AND OXYGEN DEBT
Active skeletal muscles have a huge demand for ATP.
Creatine phosphate can quickly replenish some ATP.
Muscles store glycogen for rapid utilization of glucose.
AEROBIC RESPIRATION ANAEROBIC RESPIRATION
(Lactic Acid Fermentation)
Produces lots of ATP Produces ATP quickly
Requires lots of O2 Common when aerobic respiration is too slow
Myoglobin stores O2 in muscle cells. Common with insufficient O2 for aerobic
respiration
Lactate must be shuttled to the liver to be
converted back to pyruvate (Cori Cycle).

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Sliding Filament Theory
Thin (actin) and thick (myosin) filaments slide past each other during contraction.

Action of Myosin
1. Binding of ATP
Myosin releases actin.

2. ATP hydrolysis
Myosin reattaches to actin (forms crossbridge
closer to the center of the sarcomere)

3. Pi is released (Power Stroke)
Myosin pulls actin toward the center of the
sarcomere

4. ADP is released
Myosin is now tightly bound to actin (rigor)

Muscle Contraction
Contraction
1. Acetylcholine (Ach) is released by a somatic motor neuron.
2. Ach binds Ach receptors/Na+ channels on the muscle fiber (influx of Na+).
3. Depolarization above threshold opens voltage-gated Na+ channels initiating an AP.
4. Voltage-gated Ca2+ channels open in the sarcoplasmic reticulum (outflux of Ca2+).
5. Ca2+ binds to troponin (which is bound to tropomyosin).
6. Troponin removes tropomyosin off of the myosin-binding sites of actin.
7. The myosin powerstroke ensues.

Relaxation
8. Ca2+ is actively pumped back into the sarcoplasmic reticulum.
9. Troponin releases Ca2+.
10. Tropomyosin binds to the myosin-binding sites of actin.

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5.4 Circulatory System
FUNCTIONS OF THE CIRCULATORY SYSTEM
Circulation to Cells Removal of Metabolic Waste Distributes
O2 (from lungs) CO2 (to lungs) Immune cells, antibodies
Nutrients, Ions, H2O Ammonia/Urea and H2O Clotting factors
(from intestines/liver) (to the kidneys)
Hormones Heat (to skin--thermoregulation)

Four-Chambered Heart

AV Valves – tricuspid and bicuspid (a.k.a. mitral valve)
Semilunar Valves – pulmonary valve, aortic valve

DIASTOLE SYSTOLE
1. Atria contract 1. Ventricles contract
2. Ventricles fill from atria 2. AV valves close (“lub”)
3. Semilunar valves open
4. Blood flows into aorta / pulmonary artery
5. Semilunar valves close (“dub”)

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Blood Vessels
The entire circulatory system (including the heart) is lined (inner lining) in endothelial cells.

ARTERIES VEINS
carry blood away from the heart carry blood toward the heart
high pressure very low pressure
pressure reservoir volume reservoir
elastic and lined with smooth muscle larger veins are lined with some smooth muscle
no valves valves prevent backflow

Arterioles
Site of most peripheral resistance
Regulate blood flow to individual tissues (variable resistance)
Regulated locally to match metabolic needs (by paracrines)
Regulated by ANS (sympathetic) and hormones

Capillaries
Very narrow blood vessels; wide enough for a single RBC to pass through
Site of gas/nutrient/waste exchange
Site of significant peripheral resistance

Portal Circulation
Circulation between capillary beds
Hypophyseal Portal System – hypothalamus to pituitary gland
Hepatic Portal System – from small intestine to liver
Renal Portal System – from glomerulus to peritubular capillaries

Flow Characteristics
Pressure decreases over distance
Resistance is greater in smaller
vessels

CO = Cardiac Output R = Resistance

Hypertension can be caused by increased CO, increased peripheral resistance, or increased
blood volume.
Baroreceptors in the aorta and carotid arteries sense blood pressure – send sensory input to
medulla.

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Capillary Exchange
O2 and CO2 can diffuse across the cell membrane.
Capillaries are thin (one cell thick) and porous.
Nutrients, WBCs, pathogens, and water can pass through the pores (bulk flow).

Arteriolar End
Hydrostatic > Oncotic
High hydrostatic pressure
High tissue osmolarity
Water is forced out

Venular End
Oncotic > Hydrostatic
Lower hydrostatic pressure
Increased blood osmolarity
Water is forced back in

BLOOD COMPOSITION
Plasma
Mostly water
Contains proteins, ions, dissolved O2 and CO2
Volume regulated by kidneys
Erythrocytes (RBCs)
Hematocrit – percentage of RBCs in blood
Produced in the bone marrow
Aged RBCs filtered by spleen
No nucleus (short-lived)
Contain lots of hemoglobin
Transport O2 to tissues; CO2 to lungs
Leukocytes (WBCs)
Mediators of the immune system
Clotting Factors
Platelets produced in the bone marrow
Fibrinogen/clotting proteins made in liver

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Mechanism of Clotting/Coagulation
1. Vasoconstriction (paracrine-induced)
2. Tissue damage attracts platelets (forms platelet plug)
3. Tissue damage sets off a coagulation cascade
End result is conversion of fibrinogen to fibrin
Clot is composed mostly of platelets and fibrin

Oxygen Transport by the Blood
Hemoglobin can bind up to four O2 molecules
Binding is cooperative (sigmoidal binding curve).
Hemoglobin vs. myoglobin
Bohr Effect - H+ and CO2 decrease the affinity of hemoglobin for O2
CO2 + H2O  H2CO3  H+ + HCO3-

CO2 Transport in Blood
1. CO2(aq)
2. CO2 + H2O  H2CO3  H+ + HCO3-
3. Bound to Hemoglobin

CONTROL OF THE CIRCULATORY SYSTEM
Heart Vascular Smooth Muscle
ANS via the medulla Paracrines -- regulated locally to match
(both sympathetic and parasympathetic) metabolic needs
Hormones ANS (sympathetic)
Hormones (epinephrine, ADH, ANF, etc.)

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5.5 Lymphatic/Immune System
FUNCTIONS OF THE LYMPH SYSTEM
1. Recirculation of Plasma
Plasma lost from the capillaries is returned to the circulatory system.
Lymph is emptied into the venous circulation via the thoracic duct.
Fluid flow is unidirectional as lymph vessels contain valves (just like veins).
2. Filter/Destroy Pathogens
Lymph nodes serve as reservoirs for macrophages and lymphocytes.
Pathogens are often first encountered by the immune system in the lymph nodes.
The spleen also acts as a reservoir for macrophages.
3. Absorption of Larger Glycerides
Larger glycerides are absorbed directly into the lymph system from the small intestine.
They enter the circulatory system via the thoracic duct.

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Immune System
IMMUNE SYSTEM
INNATE IMMUNITY ADAPTIVE IMMUNITY
Nonspecific Specific
Faster response Slower response
Inflammatory response Humoral Cell-Mediated
Complement system Antibody-mediated Contact-dependent
Receptor-mediated

IMMUNE SYSTEM CELLS
INNATE IMMUNE CELLS ADAPTIVE IMMUNE CELLS
Macrophages (phagocytes) T lymphocytes (T cells)
Neutrophils (phagocytes) B lymphocytes (B cells)

FUNCTIONS OF IMMUNE SYSTEM TISSUES
TISSUE FUNCTIONS
Bone Marrow Hematopoietic stem cells produce all leukocytes (WBCs)
Filters/destroys pathogens
Spleen
Reservoir of monocytes (immature macrophages)
Thymus T cell maturation (including removal of self-antigen recognizing T cells)
Lymph Nodes Filters/destroys pathogens; reservoir of macrophages and lymphocytes

Innate Immunity
Phagocytes ingest foreign material (macrophages and neutrophils)
Tears and saliva contain lysozyme; stomach pH ~ 2
Epithelial tissues form a barrier (skin, lining of GI tract and respiratory tract)
Complement system – system of proteins effecting lysis of pathogens or virus-infected cells

Inflammatory Response
Attracts immune cells
Promotes tissue repair
Mediated through cytokines

Natural Killer (NK) Cells
Recognize virus-infected cells and induce apoptosis

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Humoral Immunity
Humoral immunity is mediated by antibodies (immunoglobulins) and B cells.
Antibodies are expressed on the surface of B cells (B cell receptors).
Antibody binding tags an antigen for phagocytosis and activates the complement system.
Variable (VDJ) recombination produces antibodies for any antigen.

B-Cells
B cells are produced in the bone marrow.
B cells recognizing self-antigens are eliminated in the bone marrow (clonal deletion).
B cells are Antigen Presenting Cells and can activate Th cells (Cell-Mediated Immunity).

Primary Humoral Response
1st exposure to a pathogen
Takes 5-7 days

Mechanism
1. Antigen recognition activates a naive B cell
2. Naive B cell proliferates (clonal selection)
3. Memory cells and plasma cells are produced
4. Plasma cells secrete antibodies

Secondary Humoral Response
2nd exposure to a pathogen
Memory cell response is much faster

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Cell-Mediated Immunity
Cell-mediated immunity is mediated by Helper T cells and Cytotoxic T cells.
T cells are produced in the bone marrow.
T cells recognizing self-antigens are eliminated in the thymus (clonal deletion).
T cells only recognize antigens presented with MHC (Major Histocompatibility Complex).

Helper T Cells (Th)
CD4+ (recognize MHC II-bound antigen)
Presentation by APC (macrophage, B cell, dendritic cell)
Secrete cytokines activating immune cells

Cytotoxic T cells (Tc)
CD8+ (recognize MHC I-bound antigen)
Presentation by any nucleated cell
Induce apoptosis of tumor or virus-infected cells

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5.6 Digestive System
Ingestion
Mastication breaks up food into smaller pieces.
Saliva lubricates food and contains enzymes.
Amylase converts starch to disaccharides.
Lipase breaks down fats (minimal).
Lysozyme is anti-bacterial.
The epiglottis prevents food/liquids from entering the trachea.
The esophagus is lined in smooth muscle which propels food to
the stomach (peristalsis).

FUNCTIONS OF THE STOMACH
1. Storage/Churning of Food
Stored until the small intestine has room (regulated by the pyloric
sphincter)
The pyloric sphincter is controlled by the enteric nervous system.
The pyloric sphincter also closes in response to cholecystokinin
(from the duodenum).
Gastric smooth muscle churns (mixes) food aiding in digestion.
2. Partial Digestion
a. Partial acid hydrolysis of proteins and carbohydrates (pH ~ 2)
HCl is secreted by parietal cells.
The stomach is lined in mucus to prevent self-digestion.
b. Pepsin functions in proteolysis.
Produced/secreted as a zymogen (pepsinogen) by gastric chief cells.
Converted to active form by acid-catalyzed proteolysis in the stomach
c. Gastric lipase is involved in a small amount of lipid catabolism.

Regulation
Gastrin secreted by G cells stimulates secretion of HCl and pepsinogen.
Histamine stimulates secretion of HCl.
Somatostatin inhibits HCl and gastrin secretion.
Stimulated by the parasympathetic nervous system; inhibited by the sympathetic)
Also regulated by the enteric nervous system

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 FUNCTIONS OF THE LIVER
1. Production of Bile (from cholesterol)
Bile aids in digestion of lipids (emulsification) and absorption of fat-
soluble vitamins.
Bile is stored in the gall bladder.
Bile is delivered to the duodenum via the common bile duct.
Bile is reabsorbed in the ileum.
2. Regulation of Blood Glucose
Insulin stimulates glycogen synthesis (lowers blood sugar).
Glucagon, epinephrine, and cortisol stimulate glycogenolysis &
gluconeogenesis (raises blood sugar).
Cori Cycle - Lactate produced in muscles is converted back into pyruvate
and ultimately glucose.
3. Detoxification
Drugs/toxins are converted to less harmful substances.
4. Lipid Metabolism
Production of lipoproteins (from chylomicrons)
Lipoproteins carry cholesterol/triglycerides to the tissues.
5. Production of Plasma Proteins
Albumin, fibrinogen, other clotting factors
6. Various other functions

FUNCTIONS OF THE PANCREAS
1. Production/Transport of Enzymes
amylase – converts polysaccharides to disaccharides
lipase – converts triglycerides to fatty acids and monoglycerides
nucleases – hydrolyze nucleic acids
protease zymogens – inactive precursors activated by proteolysis
trypsinogen – activated by enterokinase (and trypsin) in the duodenum
chymotrypsinogen –activated by trypsin in the duodenum
procarboxypeptidase – activated by enterokinase in the duodenum
Enzyme secretion stimulated by cholecystokinin
Transported to the duodenum via the pancreatic duct
2. Secretion of Bicarbonate (Exocrine)
Keeps the pH in duodenum slightly basic
Secretion stimulated by secretin (from the duodenum)
Delivered to the duodenum via the pancreatic duct
3. Produces Hormones (Endocrine)
Hormones are produced by cells in regions called Islets of Langerhans.
a. Glucagon is secreted by  cells (raises blood sugar).
Stimulates glycogenolysis / gluconeogenesis by the liver
Stimulates release of fats into the blood stream by adipocytes
b. Insulin is secreted by  cells (lowers blood sugar).
Stimulates glycogen synthesis by liver and skeletal muscle
Stimulates glucose uptake by skeletal muscle and adipose tissue
c. Somatostatin is secreted by  cells.
Inhibits digestion (overall)
Inhibits HCl secretion by parietal cells
Inhibits secretion of gastrin, histamine, secretin, and cholecystokinin
Inhibits glucagon and insulin secretion
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Small Intestine
Duodenum – site of most digestion and absorption
Jejunum / Ileum –site of specialized absorption
Brush Border Cells – microvilli-covered regions of the
lumen of the small intestine

FUNCTIONS OF THE SMALL INTESTINE
1. Absorption of Food and Water
Carbohydrates - Monosaccharides enter epithelial cells via symport with Na+
(2 active transport).
They exit epithelial cells via facilitated diffusion and are taken up by the capillaries.
Proteins - Amino acids enter epithelial cells via symport with Na+ (2 active transport).
They exit epithelial cells via facilitated diffusion and are taken up by the capillaries.
Fats - Fatty acids and monoglycerides diffuse into epithelial cells.
They’re converted back into triglycerides and packaged into chylomicrons.
Chylomicrons exit epithelial cells into lacteals of the lymphatic system.
The lymphatic system empties into the venous circulation at the thoracic duct.
2. Production of Enzymes
Enterokinase – Converts trypsinogen to trypsin
Trypsin activates other proteases
Brush Border Enzymes – Responsible for final digestion of disaccharides and peptides
3. Digestion
Carbohydrates - Pancreatic amylase converts polysaccharides into disaccharides.
Brush border enzymes convert disaccharides into monosaccharides.
Proteins - Pancreatic proteases convert peptides to di- and tri-peptides.
Brush border proteases convert di- and tripeptides to amino acids.
Fats - Bile emulsifies fat droplets into smaller micelles.
Lipases convert triglycerides to fatty acids and monoglycerides.
4. Neutralization of Stomach Acid
Bicarbonate from the pancreas neutralizes HCl (pH ~ 8).
5. Hormone Secretion (Endocrine)
Cholecystokinin (CCK) – Secreted due to the presence of fatty acids and amino acids
Causes the pancreas to release digestive enzymes
Causes the gall bladder to release bile
secretin – secreted due to presence of acid and causes pancreas to release bicarbonate
into the duodenum

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 FUNCTIONS OF THE LARGE INTESTINE
1. Absorption of water, electrolytes, and vitamins
There are hundreds of species of bacteria in the colon.
They most notably produce vitamin K and biotin (vitamin B7).
They also produce GAS.
2. Formation of Feces (compaction)
3. Storage of Feces in the Rectum

Regulation
Muscular Control – The GI tract is lined in smooth muscle.
Peristalsis – contraction of smooth muscle behind the bolus/chime; relaxation ahead
Controlled by the autonomic and enteric nervous systems
The autonomic and enteric nervous systems also regulate some of the GI secretions.
Endocrine Control – The presence of chime causes the release of GI hormones.
Paracrines (like histamine) are also involved in local regulation.

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5.7 Respiratory System
FUNCTIONS OF THE RESPIRATORY SYSTEM
1. Gas Exchange
Exchange of O2 / CO2 by the alveoli
2. Thermoregulation
A significant amount of heat is lost to expired air.
3. Protection from Pathogens and Particulates
Nose hairs and mucus contain immunoglobulins.
Goblet cells secrete the mucus.
Cilia propel mucus toward the pharynx.
Macrophages in the alveoli phagocytose pathogens & particulates.
4. pH Regulation
Removal of CO2 reduces acidity.
Hyperventilation vs. hypoventilation

Structure
1. Conducting System
mouth/nose → nasal cavity → pharynx → larynx →
trachea → primary bronchi → bronchi → bronchioles
Warms the air to prevent core heat loss
Humidifies air to keep alveoli from drying out
Removes pathogens / particulates

2. Exchange Surface
Alveoli
Bronchioles

3. Muscles/Bones of the Thoracic Cavity
Diaphragm
Abdominal muscles
Intercostals
Rib cage

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Alveolar Structure
Thin-walled, air-filled sacs with a huge surface area that are surrounded by capillaries
Coated in surfactant (protein phospholipid mixture) which reduces surface tension
Type I alveolar cells – make up 95% of alveolar walls and are the site of gas exchange
Type II alveolar cells – secrete surfactant
Gas exchange results from diffusion due to differential partial pressures (Henry’s Law).

Ventilation
Inspiration is caused by contraction of the diaphragm and expansion of the rib cage.
(The diaphragm is a skeletal muscle.)
The lungs are surrounded to two pleural sacs (inner/outer) separated by a thin layer of fluid.
The outer pleural sac is connected to the diaphragm and walls of the thoracic cavity.
Expansion of the lungs lowers the pressure inside them (Boyle’s Law).

Expiration is usually passive elastic recoil of the lungs (resiliency).
Due to relaxation of diaphragm and intercostals (rib cage) and alveolar surface tension
Forced expiration involves contraction of the abdominal and internal intercostal muscles

Control
The diaphragm is innervated by the Somatic Nervous System (like all skeletal muscle).
Inspiration can be both voluntary and involuntary (controlled by the medulla).
Result in Increased Ventilation
High plasma [CO2]
Low plasma [O2]
Low plasma pH

REGULATION OF BRONCHIOLE RESISTANCE
Bronchoconstriction Bronchodilation
Parasympathetic NS Expired CO2 levels
Histamine Epinephrine
Leukotrienes
(inflammation)

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5.8 Urinary System
FUNCTIONS OF THE URINARY SYSTEM
1. Regulation of Blood Pressure (and extracellular fluid volume)
Integrated with the cardiovascular system
2. Osmoregulation and Maintenance of Ion Balance
3. Acid-base Balance (either HCO3- or H+ can be excreted) Homeostasis
Integrated with the respiratory system
4. Removal of Soluble Nitrogenous Waste (including urea and uric acid)
5. Regulation of Red Blood Cell Synthesis (secretion of erythropoietin)

Urination is controlled by the internal and external urethral sphincter muscles
Internal urethral sphincter – smooth muscle controlled by the autonomic nervous system
External urethral sphincter – skeletal muscle controlled by the somatic nervous system

Urine Formation
1. Filtration – Hydrostatic pressure forces plasma from the capillaries of the glomerulus into
the lumen of Bowman’s Capsule of the nephrons.
2. Reabsorption – Much of the filtrate is recovered from the nephron tubule into the
peritubular capillaries.
H2O, ions, glucose, amino acids, proteins, and urea are reabsorbed.
3. Secretion – Certain solutes are concentrated in the urine from the peritubular capillaries
K+, H+, and organic molecules (including drugs/toxins) are added to the filtrate.

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Glomerular Filtration Rate (GFR) is regulated by afferent (primarily) and efferent arterioles.

Proximal Tubule – The site of most reabsorption

Loop of Henle – Responsible for dilute urine
A countercurrent multiplier
The descending limb is permeable to water, but impermeable to ions.
The ascending limb is impermeable to water. Ions are actively transported out.

Distal Nephron (distal tubule and collecting duct) – the site of most secretion
Responsible for concentrated urine

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 HORMONAL REGULATION
HORMONE EFFECT CAUSE FOR RELEASE
ADH Increases water reabsorption by distal nephron Low blood volume
(vasopressin) High blood osmolarity
Increases Na reabsorption by the distal nephron
+
Low blood pressure
Aldosterone Increases K+ secretion by the distal nephron High [K+]
Increased water retention and thirst
Increases Na+ and water excretion High blood volume
ANF +
(decreases Na reabsorption by collecting duct)
Vasodilation

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5.9 Nervous System
Nervous System
High level control and integration of body systems
Adaptive capability to external influences

Central Nervous System
Includes the brain and spinal cord
Controls and integrates body systems

Brain Stem
Medulla (oblongata) – controls some involuntary functions
including blood pressure, breathing, vomiting, and
swallowing
Pons – relay center between the cerebellum and cerebrum
Midbrain – relay center for visual and auditory impulses

Cerebellum
Integration/coordination of movement

Diencephalon
Thalamus - integrating/relay center
Hypothalamus – homeostasis
Influences the endocrine system
Influences the autonomic nervous system
Pituitary gland
Pineal gland

Cerebral Cortex (Cerebrum)
Site of higher brain functions
Divided into two hemispheres connected by corpus callosum
Right hemisphere controls motor functions for left side and
vice versa

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Peripheral Nervous System
Includes all neurons outside the brain and spinal chord
Includes the Somatic and Autonomic Nervous System
Neurons are typically either afferent or efferent.

Somatic Nervous System
Voluntary control of skeletal muscles
Somatic motor neurons
Have long axon to effector
Use acetylcholine as their neurotransmitter
Have cell bodies in the spinal cord or brain
Somatic sensory neurons
Have long dendrite to cell body
Have cell bodies in the dorsal root ganglion
Have axon that extends to spinal cord or brain stem

Autonomic Nervous System
Involuntary control of: SYMPATHETIC PARASYMPATHETIC
1. Smooth muscle “fight or flight” “rest and digest”
2. Cardiac muscle
Increase energy availability Store energy
3. Endocrine/exocrine glands
Activated by stress
Important for maintaining homeostasis
Antagonistic control between sympathetic and parasympathetic branches

There are two neurons in series connecting the CNS to effector.
A postganglionic neuron has its cell body in an autonomic ganglion.

Integration with the Endocrine System
The hypothalamus coordinates control of both the autonomic nervous system and the
endocrine system to maintain homeostasis. The hypothalamus specifically regulates the
pituitary gland (endocrine system) and the medulla (ANS).

Examples of Feedback Control
If body temperature drops, the sympathetic PNS causes vasoconstriction of the blood
vessels to the skin.
If body temperature rises, the sympathetic nervous system activates sweating.

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Neuron
Cell body (soma) – contains nucleus and most organelles
and controls metabolic activity and biosynthesis
Axon – transmits impulses away from the cell body
Dendrite – receives signals and transmits it toward the cell
body
Myelin Sheath – insulating sheath around axons
Made by glial cells (Schwann cells in the PNS and
oligodendrocytes in the CNS)
Glial Cells (a.k.a. neuroglia) – non-neuronal cells that
provide support/protection to neurons
Nodes of Ranvier – gaps in myelin sheath (faster impulse
propagation with saltatory conduction)
Synapse – site of impulse propagation between cells (via
neurotransmitters)

Synaptic Transmission
Presynaptic Neuron
1. An action potential reaches the synaptic knobs
2. Voltage-gated Ca2+ channels open
3. Uptake of Ca2+
4. Exocytosis of neurotransmitter

Postsynaptic Cell
5. Neurotransmitter binds receptors
6. Ion channels open
7. Polarization is increased or decreased
8. Neurotransmitter activity is terminated
Diffuses away, degraded, or re-uptake

EPSP – Excitatory postsynaptic potential
IPSP – Inhibitory postsynaptic potential

Neurotransmitter binding can be excitatory (EPSP) or inhibitory (IPSP). The additive effect of
EPSPs and IPSPs at all synapses determines whether an action potential is generated
(summation).

Synaptic Fatigue – inhibition under constant or persistent stimulus; caused by depletion of
synaptic vesicles

Neurotransmitters include acetylcholine, norepinephrine, epinephrine, serotonin,
dopamine, GABA, a few amino acids and even a couple gases

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Action Potentials
Resting Potential of a neuron is ~-70mV
Na+/K+ pump (active transport) and K+ leak channels maintain resting potential

1. Depolarization (must exceed threshold of -50mV)
2. Voltage-gated Na+ channels open
(further depolarization)
3. Voltage-gated Na+ channels close
4. Voltage-gated K+ channels open
(repolarization/hyperpolarization)
5. Voltage-gated K+ channels close
6. Resting potential restored by Na+/K+ pump

Refractory Period - Voltage-gated Na+ channels are
inactivated until the resting potential is re-established

Propagation of Action Potentials
Saltatory Conduction – Depolarization ‘jumps’ to each successive node of Ranvier speeding up
transmission

All or Nothing Principle – Strength of an action potential never varies
Intensity of a stimulus is related to the frequency of firing

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5.10 Endocrine System
Nervous System vs. Endocrine System
Nervous System – effects are fast-acting but short-lasting
Endocrine System – effects aren’t as fast-acting but are longer lasting

Endocrine vs. Exocrine
Endocrine Glands – ductless glands that release hormones into the bloodstream that bind
specific receptors on/in their target cells
Exocrine Glands – glands that release their products via ducts either into the GI tract or
outside the body
Hormone – a chemical messenger secreted into the blood for transport to a target(s)

TYPES OF HORMONES
AMINO ACID-DERIVED
Catecholamines T3 and T4
PEPTIDE STEROID
(Epinephrine,
Norepinephrine)
Water
Hydrophilic Hydrophobic Hydrophilic Hydrophobic
Solubility
Synthesis Rough ER Smooth ER Adrenal Medulla Thyroid
Transport in Carrier Protein- Carrier Protein-
Free in plasma Free in plasma
Blood bound bound
Cytoplasmic or
Target Nuclear
Cell Membrane Nuclear Cell Membrane
Receptor Receptor
Receptor
Transcription Transcription
Mechanism 2nd messenger 2nd messenger
Regulation Regulation
Fast Acting / Slow Acting /
Half-Life Short Long
Short-lived Long-lasting

The only amino-acid derived hormones to note are epinephrine, norepinephrine, T3, and T4.
The sex hormones and all hormones from the adrenal cortex are steroids.
Androgens (testosterone), estrogens and progesterone, cortisol and aldosterone
All remaining hormones are peptides (most hormones in general are peptides).

Mechanisms of Hormone Action
Enzyme Regulation
Transcriptional Regulation
Regulating solute transport across membranes

Hormone Regulation
Nervous System – hypothalamus controls anterior and posterior pituitary gland
Tropic Hormones – hormones that control other hormones
Hypothalamus controls anterior pituitary via tropic hormones
Anterior pituitary controls gonads, adrenal cortex, and thyroid via tropic hormones
Endocrine Gland itself acts as a sensor
-cells sense blood glucose levels and release insulin when they are above threshold

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Regulation of the Endocrine System
ANTERIOR PITUITARY POSTERIOR PITUITARY
FSH (gonads) Oxytocin (mammary glands, uterus)
LH (gonads) ADH (kidneys)
ACTH (adrenal cortex)
GH (generic)
Prolactin (mammary glands)

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 GLAND HORMONE TARGET FUNCTION
Hypothalamus tropic hormones anterior pituitary modify release of anterior pituitary hormones
FSH (follicle stimulating hormone) ovaries/testes follicle development / spermatogenesis
LH (luteinizing hormone) ovaries/testes ovulation / testosterone synthesis
ACTH (adrenocorticotropic hormone) adrenal cortex increase cortisol release
Anterior Pituitary
TSH (thyroid stimulating hormone) thyroid increase thyroid hormone synthesis
GH (growth hormone) bone, muscle growth
prolactin mammary glands milk production
ADH (antidiuretic hormone/vasopressin) kidneys/blood vessels water reabsorption/ vasoconstriction
Posterior Pituitary
oxytocin mammary glands / uterus milk release / contraction
T4 (thyroxin) generic increase metabolism
Thyroid T3 (triiodothyronine) generic increase metabolism
calcitonin bone lower blood Ca2+
Parathyroid PTH (parathyroid hormone) bone increase blood Ca2+
Thymus thymosin thymus T cell development (childhood)
Heart ANF (atrial natriuretic factor; aka ANP) kidneys vasodilation / increases Na+ excretion (lowers blood pressure)
glucagon (−cells) liver, muscles, adipose increase blood glucose
Pancreas insulin (β-cells) liver, muscles, adipose decrease blood glucose
somatostatin (-cells) stomach, duodenum inhibit digestion
pancreas inhibit glucagon and insulin secretion
Duodenum Cholecystokinin (CCK) Pancreas, gall bladder Secretion of digestive enzymes, bile; satiety
epinephrine heart, blood vessels, liver fight or flight
Adrenal Medulla
norepinephrine heart, blood vessels, liver fight or flight
cortisol (glucocorticoids) generic long-term stress response
Adrenal Cortex
aldosterone (mineralocorticoids) kidneys reabsorption of Na+; excretion of K+ (increases blood pressure)
erythropoietin bone marrow increase RBC synthesis
Kidneys
calcitriol bone increase blood Ca2+
Testes testosterone testes / generic spermatogenesis, secondary sex characteristics
estrogen uterus / generic menstrual cycle, secondary sex characteristics
Ovaries
progesterone uterus menstrual cycle, pregnancy

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5.11 Reproductive System
GAMETOGENESIS
FEMALE MALE
Gonads ovaries testes
Germ Cells oogonia spermatogonia
Gametes ova (ovum) spermatozoa
Products 1 ovum, 2 polar bodies 4 spermatozoa
Timing puberty → ~50 years old puberty → death

Oogenesis
1. Oogonia develop into primary oocytes prenatally (arrested in prophase I)
2. Follicle maturation
A primary oocyte splits into a secondary oocyte and first polar body concluding meiosis I
Meiosis is arrested in metaphase II
3. Ovulation
4. Fertilization
Meiosis II is only completed after fertilization

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Spermatogenesis
Spermatozoa are produced in the seminiferous tubules of the testes
Sustentacular cells regulate sperm development (provide “sustenance”)
Leydig Cells (Interstitial Cells) secrete testosterone
Maturation occurs as spermatogonia migrate towards the lumen of the seminiferous
tubules
Maturation continues in the epididymis but is completed in the female reproductive tract

Sperm are much smaller than the ovum.
Sperm contribute genetic material only (its nucleus).
The ovum contributes genetic material, organelles, and cytoplasm.

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Male Reproductive System

MALE REPRODUCTIVE ORGANS
Testes Produce sperm (seminiferous tubules)
GONADS
Secrete testosterone (Leydig cells)
EXTERNAL Penis Urethra allows passage of urine and sperm
GENITALIA Scrotum External sac allowing temperature regulation of testes
INTERNAL Accessory glands Contribute secretions to semen
GENITALIA ducts

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Female Reproductive System

FEMALE REPRODUCTIVE ORGANS
Ovaries Produce ova
GONADS
Secrete estrogen and progesterone
EXTERNAL Labia majora/minora Protect internal genitalia
GENITALIA clitoris
Vagina Receptacle for penis; birth canal
INTERNAL
Uterus Womb
GENITALIA
Fallopian Tubes Transport ova from ovary to the uterus

Uterus – Endometrium – layer of glandular epithelium shed during menstruation
Myometrium – thick layer of smooth muscle

Cervix – opening of the uterus
-dilated slightly during fertile days and greatly during childbirth

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Female Reproductive Cycle
OVARIAN CYCLE
PHASE DAYS EVENTS
Follicular 1-13 FSH stimulates follicle maturation
Phase FSH and LH stimulate production of estrogen by the maturing
follicle
Ovulation 14 A spike in LH results in release of a secondary oocyte
The follicular remains become the corpus luteum
Luteal Phase 15-28 The corpus luteum secretes estrogen and progesterone
The corpus luteum degenerates throughout the phase due to
low levels of LH
Estrogen/progesterone levels drop at the end of this phase
signaling menstruation

Pregnancy
If fertilization/implantation occurs, the placenta produces human chorionic gonadotropin
(hCG).
hCG keeps the corpus luteum from degenerating in place of LH.
The corpus luteum maintains high levels of estrogen and progesterone (first 2-3 months).
The placenta then takes over production of estrogen and progesterone for the remainder of
pregnancy.
The endometrium isn’t shed and ovulation doesn’t occur during pregnancy (LH remains
low).

Negative Feedback
LH/FSH inhibit GnRH
Estrogen inhibits GnRH, LH, FSH
Inhibin (from follicle) inhibits FSH

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 MENSTRUAL CYCLE
PHASE DAYS EVENTS
Menses 1-7 Endometrium is shed (signalled by low levels of progesterone)
Proliferative Phase 7-14 Endometrial growth (due to increasing levels of estrogen)
Secondary Phase 15-28 Endometrial cells accumulate nutrients

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Parturition
Typically occurs between weeks 38 and 40
Exact trigger(s) for the induction of labor are not known

1. Cervix softens and dilates / pelvic ligaments loosen (days leading up to labor)
2. Baby “drops” and pushes on the cervix
3. Cervical stretch triggers the release of oxytocin by the posterior pituitary gland
4. Oxytocin induces contractions
5. Contractions → stretching → contractions → stretching (positive feedback cycle)
6. Baby exits birth canal

Lactation
Prolactin stimulates milk production
Estrogen and progesterone stimulate development of breasts / mammary glands but inhibit
prolactin
Estrogen and progesterone levels fall after delivery
Prolactin levels increase ~10-fold
Suckling stimulates the release of prolactin and oxytocin (needed for milk release)

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