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Chapter 19 The Cardiovascular system: Blood Vessels Blood Vessels • Delivery system of dynamic structures that begins and ends at the heart – Arteries: carry blood away from the heart; oxygenated except for pulmonary circulation and umbilical vessels of a fetus – Capillaries: contact tissue cells and directly serve cellular needs – Veins: carry blood toward the heart Venous system Large veins (capacitance vessels) Small veins (capacitance vessels) Postcapillary venule Thoroughfare channel Arterial system Heart Large lymphatic vessels Lymph node Lymphatic system Arteriovenous anastomosis Elastic arteries (conducting vessels) Muscular arteries (distributing vessels) Lymphatic Sinusoid capillary Arterioles (resistance vessels) Terminal arteriole Metarteriole Precapillary sphincter Capillaries (exchange vessels) Figure 19.2 Structure of Blood Vessel Walls • Arteries and veins – Tunica intima, tunica media, and tunica externa • Lumen – Central blood-containing space • Capillaries – Endothelium with sparse basal lamina Tunica intima • Endothelium • Subendothelial layer Internal elastic lamina Tunica media (smooth muscle and elastic fibers) External elastic lamina Tunica externa (collagen fibers) Lumen Artery (b) Capillary network Valve Lumen Vein Basement membrane Endothelial cells Capillary Figure 19.1b Capillaries • Microscopic blood vessels • Walls of thin tunica intima, one cell thick • Pericytes help stabilize their walls and control permeability • Size allows only a single RBC to pass at a time • In all tissues except for cartilage, epithelia, cornea and lens of eye • Functions: exchange of gases, nutrients, wastes, hormones, etc. Capillaries • Three structural types 1. Continuous capillaries 2. Fenestrated capillaries 3. Sinusoidal capillaries (sinusoids) Continuous Capillaries • Abundant in the skin and muscles – Tight junctions connect endothelial cells – Intercellular clefts allow the passage of fluids and small solutes • Continuous capillaries of the brain – Tight junctions are complete, forming the bloodbrain barrier Pericyte Red blood cell in lumen Intercellular cleft Endothelial cell Basement membrane Tight junction Pinocytotic Endothelial vesicles nucleus (a) Continuous capillary. Least permeable, and most common (e.g., skin, muscle). Figure 19.3a Fenestrated Capillaries • Some endothelial cells contain pores (fenestrations) • More permeable than continuous capillaries • Function in absorption or filtrate formation (small intestines, endocrine glands, and kidneys) Pinocytotic vesicles Red blood cell in lumen Fenestrations (pores) Endothelial nucleus Intercellular cleft Basement membrane Tight junction Endothelial cell (b) Fenestrated capillary. Large fenestrations (pores) increase permeability. Occurs in special locations (e.g., kidney, small intestine). Figure 19.3b Sinusoidal Capillaries • Fewer tight junctions, larger intercellular clefts, large lumens • Usually fenestrated • Allow large molecules and blood cells to pass between the blood and surrounding tissues • Found in the liver, bone marrow, spleen Endothelial cell Red blood cell in lumen Large intercellular cleft Tight junction Nucleus of Incomplete endothelial basement cell membrane (c) Sinusoidal capillary. Most permeable. Occurs in special locations (e.g., liver, bone marrow, spleen). Figure 19.3c Capillary Beds • Interwoven networks of capillaries form the microcirculation between arterioles and venules • Consist of two types of vessels 1. Vascular shunt (metarteriole—thoroughfare channel): • Directly connects the terminal arteriole and a postcapillary venule 2. True capillaries • • 10 to 100 exchange vessels per capillary bed Branch off the metarteriole or terminal arteriole Blood Flow Through Capillary Beds • Precapillary sphincters regulate blood flow into true capillaries • Regulated by local chemical conditions and vasomotor nerves Precapillary sphincters Vascular shunt Metarteriole Thoroughfare channel True capillaries Terminal arteriole Postcapillary venule (a) Sphincters open—blood flows through true capillaries. Terminal arteriole Postcapillary venule (b) Sphincters closed—blood flows through metarteriole thoroughfare channel and bypasses true capillaries. Figure 19.4 Venules • Formed when capillary beds unite • Very porous; allow fluids and WBCs into tissues • Postcapillary venules consist of endothelium and a few pericytes • Larger venules have one or two layers of smooth muscle cells Veins • Formed when venules converge • Have thinner walls, larger lumens compared with corresponding arteries • Blood pressure is lower than in arteries • Thin tunica media and a thick tunica externa consisting of collagen fibers and elastic networks • Called capacitance vessels (blood reservoirs); contain up to 65% of the blood supply Vein Artery (a) Figure 19.1a Pulmonary blood vessels 12% Systemic arteries and arterioles 15% Heart 8% Capillaries 5% Systemic veins and venules 60% Figure 19.5 Veins • Adaptations that ensure return of blood to the heart 1. Large-diameter lumens offer little resistance 2. Valves prevent backflow of blood • • Most abundant in veins of the limbs Venous sinuses: flattened veins with extremely thin walls (e.g., coronary sinus of the heart and dural sinuses of the brain) Vascular Anastomoses • Interconnections of blood vessels • Arterial anastomoses provide alternate pathways (collateral channels) to a given body region – Common at joints, in abdominal organs, brain, and heart • Vascular shunts of capillaries are examples of arteriovenous anastomoses • Venous anastomoses are common Physiology of Circulation: Definition of Terms • Blood flow – Volume of blood flowing through a vessel, an organ, or the entire circulation in a given period • Measured as ml/min • Equivalent to cardiac output (CO) for entire vascular system • Relatively constant when at rest • Varies widely through individual organs, based on needs Physiology of Circulation: Definition of Terms • Blood pressure (BP) – Force per unit area exerted on the wall of a blood vessel by the blood • Expressed in mm Hg • Measured as systemic arterial BP in large arteries near the heart – The pressure gradient provides the driving force that keeps blood moving from higher to lower pressure areas Physiology of Circulation: Definition of Terms • Resistance (peripheral resistance) – Opposition to flow – Measure of the amount of friction blood encounters – Generally encountered in the peripheral systemic circulation • Three important sources of resistance – Blood viscosity – Total blood vessel length – Blood vessel diameter Resistance • Factors that remain relatively constant: – Blood viscosity • The “stickiness” of the blood due to formed elements and plasma proteins – Blood vessel length • The longer the vessel, the greater the resistance encountered Resistance • Frequent changes alter peripheral resistance • Varies inversely to the fourth power of vessel radius – E.g., if the radius is doubled, the resistance is 1/16 as much Resistance • Small-diameter arterioles are the major determinants of peripheral resistance • Abrupt changes in diameter or fatty plaques from atherosclerosis dramatically increase resistance – Disrupt laminar flow and cause turbulence Relationship Between Blood Flow, Blood Pressure, and Resistance • Blood flow (F) is directly proportional to the blood (hydrostatic) pressure gradient (P) – If P increases, blood flow speeds up • Blood flow is inversely proportional to peripheral resistance (R) – If R increases, blood flow decreases: F = P/R • R is more important in influencing local blood flow because it is easily changed by altering blood vessel diameter Systemic Blood Pressure • The pumping action of the heart generates blood flow • Pressure results when flow is opposed by resistance • Systemic pressure – Is highest in the aorta – Declines throughout the pathway – Is 0 mm Hg in the right atrium • The steepest drop occurs in arterioles Systolic pressure Mean pressure Diastolic pressure Figure 19.6 Arterial Blood Pressure • Reflects two factors of the arteries close to the heart – Elasticity (compliance or distensibility) – Volume of blood forced into them at any time Arterial Blood Pressure • Systolic pressure: pressure exerted during ventricular contraction • Diastolic pressure: lowest level of arterial pressure • Pulse pressure = difference between systolic and diastolic pressure Arterial Blood Pressure • Mean arterial pressure (MAP): pressure that propels the blood to the tissues MAP = diastolic pressure + 1/3 pulse pressure • Pulse pressure and MAP both decline with increasing distance from the heart Capillary Blood Pressure • Ranges from 15 to 35 mm Hg • Low capillary pressure is desirable – High BP would rupture fragile, thin-walled capillaries – Most are very permeable, so low pressure forces filtrate into interstitial spaces Venous Blood Pressure • Changes little during the cardiac cycle • Small pressure gradient, about 15 mm Hg • Low pressure due to cumulative effects of peripheral resistance Factors Aiding Venous Return 1. Respiratory “pump”: pressure changes created during breathing move blood toward the heart by squeezing abdominal veins as thoracic veins expand 2. Muscular “pump”: contraction of skeletal muscles “milk” blood toward the heart and valves prevent backflow 3. Vasoconstriction of veins under sympathetic control Valve (open) Contracted skeletal muscle Valve (closed) Vein Direction of blood flow Figure 19.7 Maintaining Blood Pressure • Requires – Cooperation of the heart, blood vessels, and kidneys – Supervision by the brain Maintaining Blood Pressure • The main factors influencing blood pressure: – Cardiac output (CO) – Peripheral resistance (PR) – Blood volume Maintaining Blood Pressure • Flow = P/PR and CO = P/PR • Blood pressure = CO x PR (and CO depends on blood volume) • Blood pressure varies directly with CO, PR, and blood volume • Changes in one variable are quickly compensated for by changes in the other variables Cardiac Output (CO) • Determined by venous return and neural and hormonal controls • Resting heart rate is maintained by the cardioinhibitory center via the parasympathetic vagus nerves • Stroke volume is controlled by venous return (EDV) Cardiac Output (CO) • During stress, the cardioacceleratory center increases heart rate and stroke volume via sympathetic stimulation – ESV decreases and MAP increases Exercise BP activates cardiac centers in medulla Activity of respiratory pump (ventral body cavity pressure) Activity of muscular pump (skeletal muscles) Parasympathetic activity Sympathetic activity Epinephrine in blood Sympathetic venoconstriction Venous return Contractility of cardiac muscle EDV ESV Stroke volume (SV) Heart rate (HR) Initial stimulus Physiological response Result Cardiac output (CO = SV x HR Figure 19.8 Control of Blood Pressure • Short-term neural and hormonal controls – Counteract fluctuations in blood pressure by altering peripheral resistance • Long-term renal regulation – Counteracts fluctuations in blood pressure by altering blood volume Short-Term Mechanisms: Neural Controls • Neural controls of peripheral resistance – Maintain MAP by altering blood vessel diameter – Alter blood distribution in response to specific demands Short-Term Mechanisms: Neural Controls • Neural controls operate via reflex arcs that involve – Baroreceptors – Vasomotor centers and vasomotor fibers – Vascular smooth muscle The Vasomotor Center • A cluster of sympathetic neurons in the medulla that oversee changes in blood vessel diameter • Maintains vasomotor tone (moderate constriction of arterioles) • Receives inputs from baroreceptors, chemoreceptors, and higher brain centers Short-Term Mechanisms: Baroreceptor-Initiated Reflexes • Baroreceptors are located in – Carotid sinuses – Aortic arch – Walls of large arteries of the neck and thorax Short-Term Mechanisms: Baroreceptor-Initiated Reflexes • Increased blood pressure stimulates baroreceptors to increase input to the vasomotor center – Inhibits the vasomotor center, causing arteriole dilation and venodilation – Stimulates the cardioinhibitory center 3 Impulses from baroreceptors stimulate cardioinhibitory center (and inhibit cardioacceleratory center) and inhibit vasomotor center. 4a Sympathetic impulses to heart cause HR, contractility, and CO. 2 Baroreceptors in carotid sinuses and aortic arch are stimulated. 4b Rate of vasomotor impulses allows vasodilation, causing R 1 Stimulus: Blood pressure (arterial blood pressure rises above normal range). Homeostasis: Blood pressure in normal range 5 CO and R return blood pressure to homeostatic range. 1 Stimulus: 5 CO and R return blood pressure to homeostatic range. Blood pressure (arterial blood pressure falls below normal range). 4b Vasomotor fibers stimulate vasoconstriction, causing R 2 Baroreceptors in carotid sinuses and aortic arch are inhibited. 4a Sympathetic impulses to heart cause HR, contractility, and CO. 3 Impulses from baroreceptors stimulate cardioacceleratory center (and inhibit cardioinhibitory center) and stimulate vasomotor center. Figure 19.9 Short-Term Mechanisms: Baroreceptor-Initiated Reflexes • Baroreceptors taking part in the carotid sinus reflex protect the blood supply to the brain • Baroreceptors taking part in the aortic reflex help maintain adequate blood pressure in the systemic circuit Short-Term Mechanisms: Chemoreceptor-Initiated Reflexes • Chemoreceptors are located in the – Carotid sinus – Aortic arch – Large arteries of the neck Short-Term Mechanisms: Chemoreceptor-Initiated Reflexes • Chemoreceptors respond to rise in CO2, drop in pH or O2 – Increase blood pressure via the vasomotor center and the cardioacceleratory center • Are more important in the regulation of respiratory rate (Chapter 22) Influence of Higher Brain Centers • Reflexes that regulate BP are integrated in the medulla • Higher brain centers (cortex and hypothalamus) can modify BP via relays to medullary centers Short-Term Mechanisms: Hormonal Controls • Adrenal medulla hormones norepinephrine (NE) and epinephrine cause generalized vasoconstriction and increase cardiac output • Angiotensin II, generated by kidney release of renin, causes vasoconstriction Short-Term Mechanisms: Hormonal Controls • Atrial natriuretic peptide causes blood volume and blood pressure to decline, causes generalized vasodilation • Antidiuretic hormone (ADH)(vasopressin) causes intense vasoconstriction in cases of extremely low BP Long-Term Mechanisms: Renal Regulation • • • Baroreceptors quickly adapt to chronic high or low BP Long-term mechanisms step in to control BP by altering blood volume Kidneys act directly and indirectly to regulate arterial blood pressure 1. Direct renal mechanism 2. Indirect renal (renin-angiotensin) mechanism Direct Renal Mechanism • Alters blood volume independently of hormones – Increased BP or blood volume causes the kidneys to eliminate more urine, thus reducing BP – Decreased BP or blood volume causes the kidneys to conserve water, and BP rises Indirect Mechanism • The renin-angiotensin mechanism – Arterial blood pressure release of renin – Renin production of angiotensin II – Angiotensin II is a potent vasoconstrictor – Angiotensin II aldosterone secretion • Aldosterone renal reabsorption of Na+ and urine formation – Angiotensin II stimulates ADH release Arterial pressure Indirect renal mechanism (hormonal) Direct renal mechanism Baroreceptors Sympathetic stimulation promotes renin release Kidney Renin release catalyzes cascade, resulting in formation of Angiotensin II Filtration ADH release by posterior pituitary Aldosterone secretion by adrenal cortex Water reabsorption by kidneys Sodium reabsorption by kidneys Blood volume Vasoconstriction ( diameter of blood vessels) Initial stimulus Physiological response Result Arterial pressure Figure 19.10 Activity of muscular pump and respiratory pump Release of ANP Fluid loss from Crisis stressors: hemorrhage, exercise, trauma, excessive body sweating temperature Conservation of Na+ and water by kidney Blood volume Blood pressure Blood pH, O2, CO2 Blood volume Baroreceptors Chemoreceptors Venous return Stroke volume Bloodborne Dehydration, chemicals: high hematocrit epinephrine, NE, ADH, angiotensin II; ANP release Body size Activation of vasomotor and cardiac acceleration centers in brain stem Heart rate Cardiac output Diameter of blood vessels Blood viscosity Blood vessel length Peripheral resistance Initial stimulus Physiological response Result Mean systemic arterial blood pressure Figure 19.11 Monitoring Circulatory Efficiency • Vital signs: pulse and blood pressure, along with respiratory rate and body temperature • Pulse: pressure wave caused by the expansion and recoil of arteries • Radial pulse (taken at the wrist) routinely used Superficial temporal artery Facial artery Common carotid artery Brachial artery Radial artery Femoral artery Popliteal artery Posterior tibial artery Dorsalis pedis artery Figure 19.12 Measuring Blood Pressure • Systemic arterial BP – Measured indirectly by the auscultatory method using a sphygmomanometer – Pressure is increased in the cuff until it exceeds systolic pressure in the brachial artery Measuring Blood Pressure • Pressure is released slowly and the examiner listens for sounds of Korotkoff with a stethoscope • Sounds first occur as blood starts to spurt through the artery (systolic pressure, normally 110–140 mm Hg) • Sounds disappear when the artery is no longer constricted and blood is flowing freely (diastolic pressure, normally 70–80 mm Hg) Variations in Blood Pressure • Blood pressure cycles over a 24-hour period • BP peaks in the morning due to levels of hormones • Age, sex, weight, race, mood, and posture may vary BP Alterations in Blood Pressure • Hypotension: low blood pressure – Systolic pressure below 100 mm Hg – Often associated with long life and lack of cardiovascular illness Homeostatic Imbalance: Hypotension • Orthostatic hypotension: temporary low BP and dizziness when suddenly rising from a sitting or reclining position • Chronic hypotension: hint of poor nutrition and warning sign for Addison’s disease or hypothyroidism • Acute hypotension: important sign of circulatory shock Alterations in Blood Pressure • Hypertension: high blood pressure – Sustained elevated arterial pressure of 140/90 or higher • May be transient adaptations during fever, physical exertion, and emotional upset • Often persistent in obese people Homeostatic Imbalance: Hypertension • Prolonged hypertension is a major cause of heart failure, vascular disease, renal failure, and stroke • Primary or essential hypertension – 90% of hypertensive conditions – Due to several risk factors including heredity, diet, obesity, age, stress, diabetes mellitus, and smoking Homeostatic Imbalance: Hypertension • Secondary hypertension is less common – Due to identifiable disorders, including kidney disease, arteriosclerosis, and endocrine disorders such as hyperthyroidism and Cushing’s syndrome Blood Flow Through Body Tissues • Blood flow (tissue perfusion) is involved in – Delivery of O2 and nutrients to, and removal of wastes from, tissue cells – Gas exchange (lungs) – Absorption of nutrients (digestive tract) – Urine formation (kidneys) • Rate of flow is precisely the right amount to provide for proper function Brain Heart Skeletal muscles Skin Kidney Abdomen Other Total blood flow at rest 5800 ml/min Total blood flow during strenuous exercise 17,500 ml/min Figure 19.13 Velocity of Blood Flow • Changes as it travels through the systemic circulation • Is inversely related to the total cross-sectional area • Is fastest in the aorta, slowest in the capillaries, increases again in veins • Slow capillary flow allows adequate time for exchange between blood and tissues Relative crosssectional area of different vessels of the vascular bed Total area (cm2) of the vascular bed Velocity of blood flow (cm/s) Figure 19.14 Autoregulation • Automatic adjustment of blood flow to each tissue in proportion to its requirements at any given point in time • Is controlled intrinsically by modifying the diameter of local arterioles feeding the capillaries • Is independent of MAP, which is controlled as needed to maintain constant pressure Autoregulation • Two types of autoregulation 1. Metabolic 2. Myogenic Metabolic Controls • Vasodilation of arterioles and relaxation of precapillary sphincters occur in response to – Declining tissue O2 – Substances from metabolically active tissues (H+, K+, adenosine, and prostaglandins) and inflammatory chemicals Metabolic Controls • Effects – Relaxation of vascular smooth muscle – Release of NO from vascular endothelial cells • NO is the major factor causing vasodilation • Vasoconstriction is due to sympathetic stimulation and endothelins Myogenic Controls • Myogenic responses of vascular smooth muscle keep tissue perfusion constant despite most fluctuations in systemic pressure • Passive stretch (increased intravascular pressure) promotes increased tone and vasoconstriction • Reduced stretch promotes vasodilation and increases blood flow to the tissue Intrinsic mechanisms (autoregulation) • Distribute blood flow to individual organs and tissues as needed Extrinsic mechanisms • Maintain mean arterial pressure (MAP) • Redistribute blood during exercise and thermoregulation Amounts of: Sympathetic pH O2 Metabolic a Receptors b Receptors controls Amounts of: Nerves Epinephrine, norepinephrine CO2 K+ Angiotensin II Hormones Prostaglandins Adenosine Nitric oxide Endothelins Myogenic controls Stretch Antidiuretic hormone (ADH) Atrial natriuretic peptide (ANP) Dilates Constricts Figure 19.15 Long-Term Autoregulation • Angiogenesis – Occurs when short-term autoregulation cannot meet tissue nutrient requirements – The number of vessels to a region increases and existing vessels enlarge – Common in the heart when a coronary vessel is occluded, or throughout the body in people in high-altitude areas Blood Flow: Skeletal Muscles • At rest, myogenic and general neural mechanisms predominate • During muscle activity – Blood flow increases in direct proportion to the metabolic activity (active or exercise hyperemia) – Local controls override sympathetic vasoconstriction • Muscle blood flow can increase 10 or more during physical activity Blood Flow: Brain • Blood flow to the brain is constant, as neurons are intolerant of ischemia • Metabolic controls – Declines in pH, and increased carbon dioxide cause marked vasodilation • Myogenic controls – Decreases in MAP cause cerebral vessels to dilate – Increases in MAP cause cerebral vessels to constrict Blood Flow: Brain • The brain is vulnerable under extreme systemic pressure changes – MAP below 60 mm Hg can cause syncope (fainting) – MAP above 160 can result in cerebral edema Blood Flow: Skin • Blood flow through the skin – Supplies nutrients to cells (autoregulation in response to O2 need) – Helps maintain body temperature (neurally controlled) – Provides a blood reservoir (neurally controlled) Blood Flow: Skin • Blood flow to venous plexuses below the skin surface – Varies from 50 ml/min to 2500 ml/min, depending on body temperature – Is controlled by sympathetic nervous system reflexes initiated by temperature receptors and the central nervous system Temperature Regulation • As temperature rises (e.g., heat exposure, fever, vigorous exercise) – Hypothalamic signals reduce vasomotor stimulation of the skin vessels – Heat radiates from the skin Temperature Regulation • Sweat also causes vasodilation via bradykinin in perspiration – Bradykinin stimulates the release of NO • As temperature decreases, blood is shunted to deeper, more vital organs Blood Flow: Lungs • Pulmonary circuit is unusual in that – The pathway is short – Arteries/arterioles are more like veins/venules (thin walled, with large lumens) – Arterial resistance and pressure are low (24/8 mm Hg) Blood Flow: Lungs • Autoregulatory mechanism is opposite of that in most tissues – Low O2 levels cause vasoconstriction; high levels promote vasodilation – Allows for proper O2 loading in the lungs Blood Flow: Heart • During ventricular systole – Coronary vessels are compressed – Myocardial blood flow ceases – Stored myoglobin supplies sufficient oxygen • At rest, control is probably myogenic Blood Flow: Heart • During strenuous exercise – Coronary vessels dilate in response to local accumulation of vasodilators – Blood flow may increase three to four times Blood Flow Through Capillaries • Vasomotion – Slow and intermittent flow – Reflects the on/off opening and closing of precapillary sphincters Capillary Exchange of Respiratory Gases and Nutrients • Diffusion of – O2 and nutrients from the blood to tissues – CO2 and metabolic wastes from tissues to the blood • Lipid-soluble molecules diffuse directly through endothelial membranes • Water-soluble solutes pass through clefts and fenestrations • Larger molecules, such as proteins, are actively transported in pinocytotic vesicles or caveolae Pinocytotic vesicles Red blood cell in lumen Endothelial cell Endothelial cell nucleus Basement membrane Tight junction Fenestration (pore) Intercellular cleft Figure 19.16 (1 of 2) Lumen Intercellular cleft Caveolae Pinocytotic vesicles Endothelial fenestration (pore) 4 Transport via vesicles or caveolae (large substances) 3 Movement Basement through membrane fenestrations 1 Diffusion through membrane (lipid-soluble substances) 2 Movement through intercellular clefts (water-soluble substances) (water-soluble substances) Figure 19.16 (2 of 2) Fluid Movements: Bulk Flow • Extremely important in determining relative fluid volumes in the blood and interstitial space • Direction and amount of fluid flow depends on two opposing forces: hydrostatic and colloid osmotic pressures Hydrostatic Pressures • Capillary hydrostatic pressure (HPc) (capillary blood pressure) – Tends to force fluids through the capillary walls – Is greater at the arterial end (35 mm Hg) of a bed than at the venule end (17 mm Hg) • Interstitial fluid hydrostatic pressure (HPif) – Usually assumed to be zero because of lymphatic vessels Colloid Osmotic Pressures • Capillary colloid osmotic pressure (oncotic pressure) (OPc) – Created by nondiffusible plasma proteins, which draw water toward themselves – ~26 mm Hg • Interstitial fluid osmotic pressure (OPif) – Low (~1 mm Hg) due to low protein content Net Filtration Pressure (NFP) • NFP—comprises all the forces acting on a capillary bed • NFP = (HPc—HPif)—(OPc—OPif) • At the arterial end of a bed, hydrostatic forces dominate • At the venous end, osmotic forces dominate • Excess fluid is returned to the blood via the lymphatic system Arteriole Venule Interstitial fluid Net HP—Net OP (35—0)—(26—1) Net HP 35 mm Capillary Net OP 25 mm NFP (net filtration pressure) is 10 mm Hg; fluid moves out Net HP—Net OP (17—0)—(26—1) Net HP 17 mm Net OP 25 mm NFP is ~8 mm Hg; fluid moves in HP = hydrostatic pressure • Due to fluid pressing against a wall • “Pushes” • In capillary (HPc) • Pushes fluid out of capillary • 35 mm Hg at arterial end and 17 mm Hg at venous end of capillary in this example • In interstitial fluid (HPif) • Pushes fluid into capillary • 0 mm Hg in this example OP = osmotic pressure • Due to presence of nondiffusible solutes (e.g., plasma proteins) • “Sucks” • In capillary (OPc) • Pulls fluid into capillary • 26 mm Hg in this example • In interstitial fluid (OPif) • Pulls fluid out of capillary • 1 mm Hg in this example Figure 19.17 Circulatory Pathways • Two main circulations – Pulmonary circulation: short loop that runs from the heart to the lungs and back to the heart – Systemic circulation: long loop to all parts of the body and back to the heart Pulmonary capillaries of the R. lung R. pulmonary L. pulmonary Pulmonary capillaries of the L. lung artery artery To systemic circulation Pulmonary trunk R. pulmonary veins From systemic circulation RA LA RV LV L. pulmonary veins (a) Schematic flowchart. Figure 19.19a Common carotid arteries to head and subclavian arteries to upper limbs Capillary beds of head and upper limbs Superior vena cava Aortic arch Aorta RA LA RV Inferior vena cava LV Azygos system Thoracic aorta Venous drainage Arterial blood Capillary beds of mediastinal structures and thorax walls Diaphragm Abdominal aorta Inferior vena cava Capillary beds of digestive viscera, spleen, pancreas, kidneys Capillary beds of gonads, pelvis, and lower limbs Figure 19.20 Differences Between Arteries and Veins Arteries Veins Delivery Blood pumped into single systemic artery—the aorta Blood returns via superior and interior venae cavae and the coronary sinus Location Deep, and protected by tissues Both deep and superficial Pathways Fairly distinct Numerous interconnections Supply/drainage Predictable supply Usually similar to arteries, except dural sinuses and hepatic portal circulation Arteries of the head and trunk Internal carotid artery External carotid artery Common carotid arteries Vertebral artery Subclavian artery Brachiocephalic trunk Aortic arch Ascending aorta Coronary artery Thoracic aorta (above diaphragm) Celiac trunk Abdominal aorta Superior mesenteric artery Renal artery Gonadal artery Common iliac artery Inferior mesenteric artery Internal iliac artery (b) Illustration, anterior view Arteries that supply the upper limb Subclavian artery Axillary artery Brachial artery Radial artery Ulnar artery Deep palmar arch Superficial palmar arch Digital arteries Arteries that supply the lower limb External iliac artery Femoral artery Popliteal artery Anterior tibial artery Posterior tibial artery Arcuate artery Figure 19.21b Ophthalmic artery Basilar artery Vertebral artery Internal carotid artery External carotid artery Common carotid artery Thyrocervical trunk Costocervical trunk Subclavian artery Axillary artery Branches of the external carotid artery • Superficial temporal artery • Maxillary artery • Occipital artery • Facial artery • Lingual artery • Superior thyroid artery Larynx Thyroid gland (overlying trachea) Clavicle (cut) Brachiocephalic trunk Internal thoracic artery (b) Arteries of the head and neck, right aspect Figure 19.22b Anterior Frontal lobe Optic chiasma Cerebral arterial circle (circle of Willis) • Anterior communicating artery • Anterior cerebral artery • Posterior communicating artery • Posterior cerebral artery Basilar artery Middle cerebral artery Internal carotid artery Mammillary body Temporal lobe Pons Occipital lobe Vertebral artery Cerebellum Posterior (d) Major arteries serving the brain (inferior view, right side of cerebellum and part of right temporal lobe removed) Figure 19.22d Vertebral artery Thyrocervical trunk Suprascapular artery Costocervical trunk Thoracoacromial artery Axillary artery Posterior circumflex humeral artery Anterior circumflex humeral artery Subscapular artery Brachial artery Deep artery of arm Common interosseous artery Common carotid arteries Left subclavian artery Right subclavian artery Brachiocephalic trunk Posterior intercostal arteries Anterior intercostal artery Internal thoracic artery Descending aorta Lateral thoracic artery Radial artery Ulnar artery Deep palmar arch Superficial palmar arch Digital arteries (b) Illustration, anterior view Figure 19.23b Hiatus (opening) for inferior vena cava Hiatus (opening) for esophagus Adrenal (suprarenal) gland Kidney Celiac trunk Abdominal aorta Lumbar arteries Ureter Median sacral artery Diaphragm Inferior phrenic artery Middle suprarenal artery Renal artery Superior mesenteric artery Gonadal (testicular or ovarian) artery Inferior mesenteric artery Common iliac artery (c) Major branches of the abdominal aorta. Figure 19.24c Common iliac artery Internal iliac artery Superior gluteal artery External iliac artery Deep artery of thigh Lateral circumflex femoral artery Medial circumflex femoral artery Obturator artery Femoral artery Adductor hiatus Popliteal artery Anterior tibial artery Posterior tibial artery Fibular artery Dorsalis pedis artery Arcuate artery Dorsal metatarsal arteries (b) Anterior view Figure 19.25b Popliteal artery Anterior tibial artery Posterior tibial artery Lateral plantar artery Medial plantar artery Fibular artery Dorsalis pedis artery (from top of foot) Plantar arch (c) Posterior view Figure 19.25c Veins of the head and trunk Dural venous sinuses External jugular vein Vertebral vein Internal jugular vein Right and left brachiocephalic veins Superior vena cava Great cardiac vein Hepatic veins Splenic vein Hepatic portal vein Renal vein Veins that drain the upper limb Subclavian vein Axillary vein Cephalic vein Brachial vein Basilic vein Median cubital vein Ulnar vein Radial vein Digital veins Veins that drain the lower limb Superior mesenteric vein Inferior vena cava Inferior mesenteric vein External iliac vein Common iliac vein Popliteal vein Internal iliac vein Posterior tibial vein Femoral vein Great saphenous vein Anterior tibial vein (b) Illustration, anterior view. The vessels of the pulmonary circulation are not shown. Small saphenous vein Dorsal venous arch Dorsal metatarsal veins Figure 19.26b Superficial temporal vein Occipital vein Posterior auricular vein External jugular vein Ophthalmic vein Facial vein Vertebral vein Internal jugular vein Superior and middle thyroid veins Brachiocephalic vein Subclavian vein Superior vena cava (b) Veins of the head and neck, right superficial aspect Figure 19.27b Superior sagittal sinus Falx cerebri Inferior sagittal sinus Cavernous sinus Straight sinus Confluence of sinuses Transverse sinuses Sigmoid sinus Jugular foramen Right internal jugular vein (c) Dural venous sinuses of the brain Figure 19.27c Brachiocephalic veins Right subclavian vein Axillary vein Brachial vein Cephalic vein Basilic vein Median cubital vein Internal jugular vein External jugular vein Left subclavian vein Superior vena cava Azygos vein Accessory hemiazygos vein Hemiazygos vein Posterior intercostals Inferior vena cava Ascending lumbar vein Median antebrachial vein Cephalic vein Basilic vein Radial vein Ulnar vein Deep palmar venous arch Superficial palmar venous arch Digital veins (b) Anterior view Figure 19.28b Cystic vein Hepatic portal system Inferior vena cava Inferior phrenic veins Hepatic veins Hepatic portal vein Superior mesenteric vein Splenic vein Suprarenal veins Renal veins Inferior mesenteric vein Gonadal veins Lumbar veins R. ascending lumbar vein L. ascending lumbar vein Common iliac veins External iliac vein (a) Schematic flowchart. Internal iliac veins Figure 19.29a Hepatic veins Inferior vena cava Right suprarenal vein Right gonadal vein Inferior phrenic vein Left suprarenal vein Renal veins Left ascending lumbar vein Lumbar veins Left gonadal vein Common iliac vein Internal iliac vein External iliac vein (b) Tributaries of the inferior vena cava. Venous drainage of abdominal organs not drained by the hepatic portal vein. Figure 19.29b Inferior vena cava (not part of hepatic portal system) Hepatic veins Liver Hepatic portal vein Small intestine Gastric veins Spleen Inferior vena cava Splenic vein Right gastroepiploic vein Inferior mesenteric vein Superior mesenteric vein Large intestine Rectum (c) The hepatic portal circulation. Figure 19.29c Common iliac vein Internal iliac vein External iliac vein Inguinal ligament Femoral vein Great saphenous vein (superficial) Popliteal vein Small saphenous vein Fibular vein Anterior tibial vein Dorsalis pedis vein Dorsal venous arch Dorsal metatarsal veins (b) Anterior view Figure 19.30b Great saphenous vein Popliteal vein Anterior tibial vein Fibular vein Small saphenous vein (superficial) Posterior tibial vein Plantar veins Deep plantar arch (c) Posterior view Digital veins Figure 19.30c