Post on 11-Jan-2016
Chapter 42
Circulatory System
Learning Objectives
Compare and contrast a closed and open circulatory system
List the 4 major components of blood Describe plasma components and function Compare and contrast erythrocytes and leukocytes Explain the function of lymphocytes Describe the function and structure of antibodies Diagram the pulmonary and systemic circulatory
systems Identify the major structures of the mammalian heart
Animal Circulatory Systems
Muscular heart pumps specialized fluid (such as blood) through tubular vessels
Blood Carries O2 and nutrients to body tissues
Carries away CO2 and wastes
Open and Closed Circulatory Systems Open circulatory system
In most invertebratesHeart pumps hemolymph into vessels that empty
into body spaces (sinuses) before returning to the heart
Closed circulatory system In some invertebrates and all vertebrates Blood is confined in blood vessels throughout the
body (does not mix with interstitial fluid)
Vertebrate Circulatory Systems
Evolved from a heart with a single series of chambers (single circuit) to a double heart that pumps blood through separate pulmonary and systemic circuits
42.2 Blood and Its Components
Plasma is an aqueous solution of proteins, ions, nutrient molecules, and gases
Erythrocytes are the oxygen carriers of the blood
Leukocytes provide the body’s front line of defense against disease
Platelets induce blood clots that seal breaks in the circulatory system
Mammalian Blood
A fluid connective tissueBlood cells (erythrocytes, leukocytes,
platelets)Suspended in a fluid matrix (plasma)
Plasma and Plasma Proteins
Contains water, ions, dissolved gases (O2 and CO2), glucose, amino acids, lipids, vitamins, hormones, and plasma proteins
Plasma proteinsAlbumins (transport, osmotic balance, pH)Globulins (transport, immunoglobins)Fibrinogen (blood clotting)
Blood Cells
Erythrocytes Contain hemoglobin (transports O2 from lungs to
body) Leukocytes
Defend body against infecting pathogens Platelets
Functional cell fragments that trigger clotting
Fig. 42.6a, p. 954
Erythrocyte (red blood cell)
Leukocyte (white blood cell)
Platelets
Fig. 42.6b, p. 954
Plasma
Leukocytes and platelets
Packed cell volume, or hematocrit
Erythrocytes
Fig. 42.7, p. 955
Leukocytes
Monocyte/macrophage EosinophilB lymphocyte
Basophil
Platelets NeutrophilT lymphocyte
Natural killer (NK) cell
Erythrocyte
Lymphoid stem cell
Myeloid stem cell
Pluripotent stem cell
megakaryocyte
(marrow) (lymph)
Types of Defense
Non-specific Specific (antibody-mediated)
Fig. 43.1, p. 974
Bacteria at injury site
Macrophages Mast cells
CytokinesCapillary
ChemokinesNeutrophils
Histamine
Neutrophils sticking to wallEndothelial cell
of capillary
1. A break in the skin introduces bacteria.
2. Activated mast cells release histamine.
3. Histamine and cytokines dilate local blood vessels.
4. Chemokines attract neutrophils, which pass between cells of the blood vessel wall.
5 Neutrophils engulf the pathogens and destroy them.
1
2
3
5
4
Adaptive (Acquired) Immunity
Triggered by antigensExogenous or endogenous macromolecules
(proteins or polysaccharides) Recognized by B cells and T cells via
antibodies Targets particular pathogens or toxin
molecules
Light and Heavy Polypeptide Chains in an Antibody Molecule
Fig. 43.11b, p. 985
b. Agglutination
Antigen Antibody
Bacterium
Immunological Memory
First encounter with an antigen elicits a primary immune response
Later exposure to the same antigen elicits a rapid secondary immune response with a greater production of antibodies
The Mammalian Heart
A four-chambered pumpTwo atria at top of heartTwo ventricles at bottom of heartAtrioventricular (AV) valves between atria and
ventriclesSemilunar (SL) valves between ventricles and aorta /
pulmonary arteries Blood is pumped into two separate circuits
Pulmonary circuit (right heart)- to the lungsSystemic circuit (left heart)- to the body
Blood Vessels Arteries carry blood away from the heart Arterioles (small branches of arteries)
deliver blood to capillaries Capillaries exchange material with
interstitial fluid Venules collect blood from capillaries Veins return blood to the heart
Blood Vessels
Blood leaves the heart in large arteries Branch into smaller arterioles
Arterioles deliver blood to capillary networksCapillaries exchange substances between blood
and interstitial fluid Small venules collect blood from capillaries
Join into larger veins that return blood to heart
Fig. 42-9, p. 957
To systemic circuit
Superior vena cava (returns blood from head, upper limbs)
Left pulmonary veins (return blood from lungs)From pulmonary circuit
Pulmonary arteries (to lungs)
Aorta
Right pulmonary veins (return blood from lungs)
AV (TV) Valve (shown open)
Left atrium
AV (MV) valve (shown open)
Right ventricle
Left ventricle
Inferior vena cava (returns blood flow from trunk, legs)
Septum
To systemic circuit
Right atrium
Semilunar (SL) valvesAtrioventricular (AV) valves
KEY
VC-from body
To body
PV
AV
Fig. 42.10, p. 958
systemic circuit
Capillary networks of head and forelimbs
pulmonary circuit
pulmonary circuit
Superior vena cava
Aorta
Pulmonary artery
Pulmonary artery
LA
Pulmonary vein
Pulmonary vein
RA
RV LV
Capillary network of right lung
Capillary network of left lung
Inferior vena cava
To lower body parts
Capillary networks of abdominal organs and lower limbs
systemic circuit
The Cardiac Cycle
Systolic pressure Contraction of ventricles pushes blood into arteries
at peak pressure or maximum pressure exerted when the heart contracts
Diastolic pressure Between contractions, blood pressure in arteries
falls to a minimum pressure or the minimum pressure in the arteries when the heart is at rest.
Systole–diastole sequence is the cardiac cycle
Fig. 42-11b, p. 959
SL valves
Left atrium
Right atrium
AV valves
Right ventricle
Left ventricle
1. Heart is fully relaxed; atria begin to fill with blood; AV and SL valves are closed.
2. Blood fills atria and pushes AV valves open; ventricles begin to fill.
3. Atria contract, filling ventricles completely.
4. Ventricles begin to contract, forcing AV valves closed; SL valves remain closed.
5. Ventricles contract fully, forcing SL valves open and ejecting blood into arteries.
Fig. 42.11a, p. 959
Systolic blood pressure
Diastolic blood pressure
Pre
ssu
re (
mm
Hg
)
Normal: 120/80 or less Prehypertension: 120/80 to 139/89 Hypertension: 140/90 or above
Arteries
Artery walls Inner endothelial layerMiddle layer of smooth muscleOuter layer of elastic fibers
Arterioles (smallest arteries) constrict and dilateRegulate flow and pressure of blood into
capillaries
Exchange Across Capillary Walls
Rate of blood flowSlower in capillaries than in arteries and veinsMaximizes time for exchange of substances between
blood and tissues Two major mechanisms drive exchange of
substances Diffusion along concentration gradientsBulk flow
Veins
Veins have thinner walls than arteriesAllows vessels to expand and contract Veins act as blood reservoirs as well as conduits
Pressure from movements of skeletal muscles and respiration help return blood to heart One-way valves prevent blood from flowing
backward
Disorders of the Circulatory System Atherosclerosis
Atherosclerosis
Cholesterol should be well below 200 mg/dL If above 240 mg/dL, statins are usually
prescribed White women between the ages of 45 and 64
years have the highest cholesterol levels High LDL and triglyceride levels are more
dangerous than high HDL levels
Magnitude of Coronary Disorders
Leading cause of death 2007: 615,651 One third of all adults has high blood pressure
and of the remaining, most have prehypertension
One is very six adults has high blood cholesterol
One third of adults are overweight, one third are obese, and 6% are extremely obese
17% of children 2-17 years old are obese
Metabolic Syndrome
Abdominal obesity
Atherogenic dyslipidemia
Raised blood pressure
Insulin resistance ± glucose intolerance
Proinflammatory state (CRP) Prothrombotic state
http://circ.ahajournals.org/cgi/content/full/109/3/433 2004