17 - University of Kentucky

Download Report

Transcript 17 - University of Kentucky

Human Anatomy & Physiology

Atlantic Cape Community Ninth Edition College

C H A P T E R

Blood

Blood Composition

• Blood – Fluid connective tissue –

Plasma

– non-living fluid matrix –

Formed elements

– living blood "cells" suspended in plasma • • •

Erythrocytes

(red blood cells, or RBCs)

Leukocytes

(white blood cells, or WBCs)

Platelets

Blood Composition

• • Spun tube of blood yields three layers – Plasma on top (~55%) – Erythrocytes on bottom (~45%) – WBCs and platelets in

Buffy coat

(< 1%)

Hematocrit

Figure 17.1 The major components of whole blood.

1 Withdraw blood and place in tube.

2 Centrifuge the blood sample.

Slide 1 Formed elements Plasma • 55% of whole blood • Least dense component Buffy coat • Leukocytes and platelets • <1% of whole blood Erythrocytes • 45% of whole blood (hematocrit) • Most dense component

Figure 17.1 The major components of whole blood.

1 Withdraw blood and place in tube.

Slide 2

Figure 17.1 The major components of whole blood.

1 Withdraw blood and place in tube.

2 Centrifuge the blood sample.

Slide 3

Figure 17.1 The major components of whole blood.

1 Withdraw blood and place in tube.

2 Centrifuge the blood sample.

Slide 4 Formed elements Plasma • 55% of whole blood • Least dense component Buffy coat • Leukocytes and platelets • <1% of whole blood Erythrocytes • 45% of whole blood (hematocrit) • Most dense component

Physical Characteristics and Volume

• Sticky, opaque fluid with metallic taste • Color varies with O 2 – High O 2 content - scarlet; Low O 2 - dark red • pH 7.35–7.45

Functions of Blood

Distribution Functions

• Delivering O 2 and nutrients to body cells • Transporting metabolic wastes to lungs and kidneys for elimination • Transporting hormones from endocrine organs to target organs © 2013 Pearson Education, Inc.

Regulation Functions

• Maintaining body temperature by absorbing and distributing heat • Maintaining normal pH using buffers; alkaline reserve of bicarbonate ions • Maintaining adequate fluid volume in circulatory system © 2013 Pearson Education, Inc.

Protection Functions

Blood Plasma

• 90% water • Over 100 dissolved solutes – Nutrients, gases, hormones, wastes, proteins, inorganic ions – Plasma proteins most abundant solutes • Remain in blood; not taken up by cells • Proteins produced mostly by liver • 60% albumin; 36% globulins; 4% fibrinogen © 2013 Pearson Education, Inc.

Table 17.1 Composition of Plasma (1 of 2)

Table 17.1 Composition of Plasma (2 of 2)

Albumin

Formed Elements

• Only WBCs are complete cells • RBCs have no nuclei or other organelles • Platelets are cell fragments • Most formed elements survive in bloodstream only few days • Most blood cells originate in bone marrow and do not divide © 2013 Pearson Education, Inc.

Figure 17.2 Photomicrograph of a human blood smear stained with Wright's stain.

Platelets Erythrocytes Monocyte

Neutrophils Lymphocyte

Erythrocytes

• Biconcave discs, anucleate, essentially no organelles • Diameters larger than some capillaries • Filled with hemoglobin (Hb) for gas transport • Contain plasma membrane protein

spectrin

Figure 17.3 Structure of erythrocytes (red blood cells).

Side view (cut) 2.5 µm 7.5 µm

Top view

Erythrocytes

• Structural characteristics contribute to gas transport – Biconcave shape—huge surface area relative to volume – >97% hemoglobin (not counting water) – No mitochondria; ATP production anaerobic; do not consume O 2 they transport • Superb example of complementarity of structure and function © 2013 Pearson Education, Inc.

Erythrocyte Function

Hemoglobin Structure

•

Globin

composed of 4 polypeptide chains – Two alpha and two beta chains •

Heme

pigment bonded to each globin chain – Gives blood red color • Heme's central iron atom binds one O 2 • Each Hb molecule can transport four O 2 • Each RBC contains 250 million Hb molecules © 2013 Pearson Education, Inc.

Figure 17.4 Structure of hemoglobin.



Globin chains Heme group



Globin chains Hemoglobin consists of globin (two alpha and two beta polypeptide chains) and four heme groups.

Iron-containing heme pigment.

Hemoglobin (Hb)

• O 2 loading in lungs – Produces

oxyhemoglobin

(ruby red) • O 2 unloading in tissues – Produces

deoxyhemoglobin

hemoglobin (dark red) or reduced • CO 2 loading in tissues – 20% of CO 2 in blood binds to Hb

carbaminohemoglobin

Hematopoiesis

• Blood cell formation in red bone marrow – Composed of reticular connective tissue and blood sinusoids • In adult, found in axial skeleton, girdles, and proximal epiphyses of humerus and femur © 2013 Pearson Education, Inc.

Hematopoiesis

•

Hematopoietic stem cells

(Hemocytoblasts) – Give rise to all formed elements – Hormones and growth factors push cell toward specific pathway of blood cell development – Committed cells cannot change • New blood cells enter blood sinusoids © 2013 Pearson Education, Inc.

Erythropoiesis: Red Blood Cell Production

• Stages –

Myeloid stem cell proerythroblast

transformed into – In 15 days proerythroblasts develop into

basophilic

, then

polychromatic

, then

orthochromatic erythroblasts

, and then into

reticulocytes

Erythropoiesis

• As myeloid stem cell transforms 1. Ribosomes synthesized 2. Hemoglobin synthesized; iron accumulates 3. Ejection of nucleus; formation of reticulocyte (young RBC) • Reticulocyte ribosomes degraded; Then become mature erythrocytes • Reticulocyte count indicates rate of RBC formation © 2013 Pearson Education, Inc.

Figure 17.5 Erythropoiesis: formation of red blood cells.

Stem cell Committed cell Developmental pathway Phase 1 Ribosome synthesis Phase 2 Hemoglobin accumulation Phase 3 Ejection of nucleus Hematopoietic stem cell (hemocytoblast) Proerythroblast Basophilic erythroblast Polychromatic erythroblast Orthochromatic erythroblast Reticulocyte Erythrocyte

Regulation of Erythropoiesis

• Too few RBCs leads to tissue hypoxia • Too many RBCs increases blood viscosity • > 2 million RBCs made per second • Balance between RBC production and destruction depends on – Hormonal controls – Adequate supplies of iron, amino acids, and B vitamins © 2013 Pearson Education, Inc.

Hormonal Control of Erythropoiesis

• Hormone

Erythropoietin

(EPO) – Direct stimulus for erythropoiesis – Always small amount in blood to maintain basal rate • High RBC or O 2 levels depress production – Released by kidneys (some from liver) in response to

hypoxia

Hormonal Control of Erythropoiesis

• Causes of hypoxia – Decreased RBC numbers due to hemorrhage or increased destruction – Insufficient hemoglobin per RBC (e.g., iron deficiency) – Reduced availability of O 2 (e.g., high altitudes) © 2013 Pearson Education, Inc.

Hormonal Control of Erythropoiesis

• Effects of EPO – Rapid maturation of

committed

marrow cells – Increased circulating reticulocyte count in 1– 2 days • Some athletes abuse artificial EPO – Dangerous consequences • Testosterone enhances EPO production, resulting in higher RBC counts in males © 2013 Pearson Education, Inc.

Figure 17.6 Erythropoietin mechanism for regulating erythropoiesis.

Slide 1 5 O 2 -carrying ability of blood rises.

4 Homeostasis: Normal blood oxygen levels Enhanced erythropoiesis increases RBC count.

3 Erythropoietin stimulates red bone marrow.

1 Stimulus: Hypoxia (inadequate O 2 delivery) due to • Decreased RBC count • Decreased amount of hemoglobin • Decreased availability of O 2 2 Kidney (and liver to a smaller extent) releases erythropoietin.

Figure 17.6 Erythropoietin mechanism for regulating erythropoiesis.

Slide 2 Homeostasis: Normal blood oxygen levels 1 Stimulus: Hypoxia (inadequate O 2 delivery) due to • Decreased RBC count • Decreased amount of hemoglobin • Decreased availability of O 2

Figure 17.6 Erythropoietin mechanism for regulating erythropoiesis.

Slide 3 Homeostasis: Normal blood oxygen levels 1 Stimulus: Hypoxia (inadequate O 2 delivery) due to • Decreased RBC count • Decreased amount of hemoglobin • Decreased availability of O 2 2 Kidney (and liver to a smaller extent) releases erythropoietin.

Figure 17.6 Erythropoietin mechanism for regulating erythropoiesis.

Slide 4 Homeostasis: Normal blood oxygen levels 3 Erythropoietin stimulates red bone marrow.

Figure 17.6 Erythropoietin mechanism for regulating erythropoiesis.

Slide 5

4 Homeostasis: Normal blood oxygen levels Enhanced erythropoiesis increases RBC count.

3 Erythropoietin stimulates red bone marrow.

Figure 17.6 Erythropoietin mechanism for regulating erythropoiesis.

Slide 6 5 O 2 -carrying ability of blood rises.

4 Homeostasis: Normal blood oxygen levels Enhanced erythropoiesis increases RBC count.

3 Erythropoietin stimulates red bone marrow.

Dietary Requirements for Erythropoiesis

• Nutrients—amino acids, lipids, and carbohydrates • Iron – Available from diet – 65% in Hb; rest in liver, spleen, and bone marrow – Free iron ions toxic • Stored in cells as ferritin and hemosiderin • Transported in blood bound to protein transferrin • Vitamin B 12 and folic acid necessary for DNA synthesis for rapidly dividing cells (developing RBCs) © 2013 Pearson Education, Inc.

Fate and Destruction of Erythrocytes

• Life span: 100–120 days – No protein synthesis, growth, division • Old RBCs become fragile; Hb begins to degenerate • Get trapped in smaller circulatory channels especially in spleen • Macrophages engulf dying RBCs in spleen © 2013 Pearson Education, Inc.

Fate and Destruction of Erythrocytes

• Heme and globin are separated – Iron salvaged for reuse – Heme degraded to yellow pigment

bilirubin

– Liver secretes bilirubin (in bile) into intestines • Degraded to pigment

urobilinogen

• Pigment leaves body in feces as

stercobilin

Figure 17.7 Life cycle of red blood cells.

1 Low O 2 levels in blood stimulate kidneys to produce erythropoietin.

2 Erythropoietin levels rise in blood.

3 Erythropoietin and necessary raw materials in blood promote erythropoiesis in red bone marrow.

5 Aged and damaged red blood cells are engulfed by macrophages of spleen, liver, and bone marrow; the hemoglobin is broken down.

Hemoglobin Heme Globin Bilirubin is picked up by the liver.

Iron is stored as ferritin or hemosiderin.

Amino acids 4 New erythrocytes enter bloodstream; function about 120 days.

Iron is bound to transferrin and released to blood from liver as needed for erythropoiesis.

Bilirubin is secreted into intestine in bile where it is metabolized to stercobilin by bacteria.

Circulation 6 Raw materials are made available in blood for erythrocyte synthesis.

Stercobilin is excreted in feces.

Food nutrients (amino acids, Fe, B 12 , and folic acid) are absorbed from intestine and enter blood.

Slide 1

Figure 17.7 Life cycle of red blood cells.

1 Low O 2 levels in blood stimulate kidneys to produce erythropoietin.

Slide 2

Figure 17.7 Life cycle of red blood cells.

1 Low O 2 levels in blood stimulate kidneys to produce erythropoietin.

2 Erythropoietin levels rise in blood.

Slide 3

Figure 17.7 Life cycle of red blood cells.

1 Low O 2 levels in blood stimulate kidneys to produce erythropoietin.

2 Erythropoietin levels rise in blood.

3 Erythropoietin and necessary raw materials in blood promote erythropoiesis in red bone marrow.

Slide 4

Figure 17.7 Life cycle of red blood cells.

1 Low O 2 levels in blood stimulate kidneys to produce erythropoietin.

2 Erythropoietin levels rise in blood.

3 Erythropoietin and necessary raw materials in blood promote erythropoiesis in red bone marrow.

Slide 5 4 New erythrocytes enter bloodstream; function about 120 days.

Figure 17.7 Life cycle of red blood cells.

5 Aged and damaged red blood cells are engulfed by macrophages of spleen, liver, and bone marrow; the hemoglobin is broken down.

Hemoglobin Heme Globin Bilirubin is picked up by the liver.

Iron is stored as ferritin or hemosiderin.

Amino acids Bilirubin is secreted into intestine in bile where it is metabolized to stercobilin by bacteria.

Circulation

Slide 6

Figure 17.7 Life cycle of red blood cells.

5 Aged and damaged red blood cells are engulfed by macrophages of spleen, liver, and bone marrow; the hemoglobin is broken down.

Hemoglobin Heme Globin Bilirubin is picked up by the liver.

Iron is stored as ferritin or hemosiderin.

Amino acids Iron is bound to transferrin and released to blood from liver as needed for erythropoiesis.

Bilirubin is secreted into intestine in bile where it is metabolized to stercobilin by bacteria.

Circulation 6 Raw materials are made available in blood for erythrocyte synthesis. Stercobilin is excreted in feces.

Food nutrients (amino acids, Fe, B 12 , and folic acid) are absorbed from intestine and enter blood.

Slide 7

Figure 17.7 Life cycle of red blood cells.

1 Low O 2 levels in blood stimulate kidneys to produce erythropoietin.

2 Erythropoietin levels rise in blood.

3 Erythropoietin and necessary raw materials in blood promote erythropoiesis in red bone marrow.

5 Aged and damaged red blood cells are engulfed by macrophages of spleen, liver, and bone marrow; the hemoglobin is broken down.

Hemoglobin Heme Globin Bilirubin is picked up by the liver.

Iron is stored as ferritin or hemosiderin.

Amino acids 4 New erythrocytes enter bloodstream; function about 120 days.

Iron is bound to transferrin and released to blood from liver as needed for erythropoiesis.

Bilirubin is secreted into intestine in bile where it is metabolized to stercobilin by bacteria.

Circulation 6 Raw materials are made available in blood for erythrocyte synthesis.

Stercobilin is excreted in feces.

Food nutrients (amino acids, Fe, B 12 , and folic acid) are absorbed from intestine and enter blood.

Slide 8

Erythrocyte Disorders

• Anemia – Blood has abnormally low O 2 -carrying capacity – Sign rather than disease itself – Blood O 2 levels cannot support normal metabolism – Accompanied by fatigue, pallor, shortness of breath, and chills © 2013 Pearson Education, Inc.

Causes of Anemia

Causes of Anemia: Blood Loss

• •

Hemorrhagic anemia

– Blood loss rapid (e.g., stab wound) – Treated by blood replacement

Chronic hemorrhagic anemia

Causes of Anemia: Low RBC Production

•

Iron-deficiency anemia

Causes of Anemia: Low RBC Production

•

Pernicious anemia

– Autoimmune disease - destroys stomach mucosa – Lack of intrinsic factor needed to absorb B 12 • Deficiency of vitamin B 12 – RBCs cannot divide 

macrocytes

Causes of Anemia: Low RBC Production

•

Renal anemia

Causes of Anemia: Low RBC Production

•

Aplastic anemia

– Destruction or inhibition of red marrow by drugs, chemicals, radiation, viruses – Usually cause unknown – All cell lines affected • Anemia; clotting and immunity defects – Treated short-term with transfusions; long term with transplanted stem cells © 2013 Pearson Education, Inc.

Causes of Anemia: High RBC Destruction

•

Hemolytic anemias

Causes of Anemia: High RBC Destruction

•

Thalassemias

Causes of Anemia: High RBC Destruction

•

Sickle-cell anemia

–

Hemoglobin S

• One amino acid wrong in a globin beta chain – RBCs crescent shaped when unload O 2 blood O 2 low or – RBCs rupture easily and block small vessels • Poor O 2 delivery; pain © 2013 Pearson Education, Inc.

Sickle-cell Anemia

• Black people of African malarial belt and descendants •

Malaria

Sickle-cell Anemia: Treatments

• Acute crisis treated with transfusions; inhaled nitric oxide • Preventing sickling – Hydroxyurea induces fetal hemoglobin (which does not sickle) formation – Blocking RBC ion channels – Stem cell transplants – Gene therapy © 2013 Pearson Education, Inc.

Figure 17.8 Sickle-cell anemia.

Val His Leu Thr Pro Glu Glu … 1 2 3 4 5 6 7 146 Normal erythrocyte has normal hemoglobin amino acid sequence in the beta chain.

Val His Leu Thr Pro Val Glu … 1 2 3 4 5 6 7 146 Sickled erythrocyte results from a single amino acid change in the beta chain of hemoglobin.

Erythrocyte Disorders

• •

Polycythemia vera

– Bone marrow cancer  excess RBCs – Severely increased blood viscosity

Secondary polycythemia

Leukocytes

• • Make up <1% of total blood volume – 4,800 – 10,800 WBCs/μl blood • Function in defense against disease – Can leave capillaries via

diapedesis

– Move through tissue spaces by ameboid motion and positive chemotaxis

Leukocytosis:

Leukocytes: Two Categories

•

Granulocytes

– Visible cytoplasmic granules –

Neutrophils, eosinophils, basophils

•

Agranulocytes

– No visible cytoplasmic granules –

Lymphocytes, monocytes

• Decreasing abundance in blood –

Never let monkeys eat bananas

Figure 17.9 Types and relative percentages of leukocytes in normal blood.

Differential WBC count (All total 4800 – Formed elements 10,800/ µ l) (not drawn to scale) Platelets Leukocytes Granulocytes Neutrophils (50 –70%) Eosinophils (2 –4%) Basophils (0.5

–1%) Erythrocytes Agranulocytes Lymphocytes (25 –45%) Monocytes (3 –8%)

Granulocytes

Neutrophils

• Most numerous WBCs • Also called Polymorphonuclear leukocytes (PMNs or polys) • Granules stain lilac; contain hydrolytic enzymes or

defensins

Eosinophils

• Red-staining granules • Bilobed nucleus • Granules lysosome-like – Release enzymes to digest parasitic worms • Role in allergies and asthma • Role in modulating immune response © 2013 Pearson Education, Inc.

Basophils

• Rarest WBCs • Nucleus deep purple with 1-2 constrictions • Large, purplish-black (basophilic) granules contain histamine – Histamine: inflammatory chemical that acts as vasodilator to attract WBCs to inflamed sites • Are functionally similar to

mast cells

Figure 17.10a Leukocytes.

Granulocytes

Neutrophil: Multilobed nucleus, pale red and blue cytoplasmic granules

Figure 17.10b Leukocytes.

Granulocytes

Eosinophil: Bilobed nucleus, red cytoplasmic granules

Figure 17.10c Leukocytes.

Granulocytes

Basophil: Bilobed nucleus, purplish-black cytoplasmic granules

Agranulocytes

Lymphocytes

• Second most numerous WBC • Large, dark-purple, circular nuclei with thin rim of blue cytoplasm • Mostly in lymphoid tissue (e.g., lymph nodes, spleen); few circulate in blood • Crucial to immunity © 2013 Pearson Education, Inc.

Lymphocytes

Monocytes

• Leave circulation, enter tissues, and differentiate into

macrophages

Figure 17.10d Leukocytes.

Agranulocytes

Lymphocyte (small): Large spherical nucleus, thin rim of pale blue cytoplasm

Figure 17.10e Leukocytes.

Agranulocytes

Monocyte: Kidney-shaped nucleus, abundant pale blue cytoplasm

Leukopoiesis

• Production of WBCs – Stimulated by 2 types of chemical messengers from red bone marrow and mature WBCs • Interleukins (e.g., IL-3, IL-5) • Colony-stimulating factors (CSFs) named for WBC type they stimulate (e.g., granulocyte-CSF stimulates granulocytes) • All leukocytes originate from hemocytoblasts © 2013 Pearson Education, Inc.

Leukopoiesis

• Lymphoid stem cells  lymphocytes • Myeloid stem cells  all others • Progression of all granulocytes – Myeloblast  band  promyelocyte mature cell  myelocyte  • Granulocytes stored in bone marrow • 3 times more WBCs produced than RBCs – Shorter life span; die fighting microbes © 2013 Pearson Education, Inc.

Leukopoiesis

• Progression of agranulocytes differs • Monocytes – live several months – Share common precursor with neutrophils – Monoblast  promonocyte  monocyte • Lymphocytes – live few hours to decades – Lymphoid stem cell  T lymphocyte precursors (travel to thymus) and B lymphocyte precursors © 2013 Pearson Education, Inc.

Figure 17.11 Leukocyte formation.

Stem cells Hematopoietic stem cell (hemocytoblast) Myeloid stem cell Lymphoid stem cell Committed cells Myeloblast Myeloblast Myeloblast Monoblast B lymphocyte precursor T lymphocyte precursor Developmental pathway Promyelocyte Promyelocyte Promyelocyte Promonocyte Eosinophilic myelocyte Basophilic myelocyte Neutrophilic myelocyte Eosinophilic band cells Basophilic band cells Neutrophilic band cells Granular leukocytes Agranular leukocytes Eosinophils (a) (b) Basophils Neutrophils (c) (d) Monocytes B lymphocytes (e) T lymphocytes (f)

Some become Some become

Macrophages (tissues) Plasma cells

Some become

Effector T cells

Leukocyte disorders

•

Leukopenia

– Abnormally low WBC count—drug induced •

Leukemias –

all fatal if untreated – Cancer  overproduction of abnormal WBCs – Named according to abnormal WBC clone involved – Myeloid leukemia involves myeloblast descendants – Lymphocytic leukemia involves lymphocytes • Acute leukemia derives from stem cells; primarily affects children • Chronic leukemia more prevalent in older people © 2013 Pearson Education, Inc.

Leukemia

• Cancerous leukocytes fill red bone marrow – Other lines crowded out  anemia; bleeding • Immature nonfunctional WBCs in bloodstream • Death from internal hemorrhage; overwhelming infections • Treatments – Irradiation, antileukemic drugs; stem cell transplants © 2013 Pearson Education, Inc.

Infectious Mononucleosis

• Highly contagious viral disease – Epstein-Barr virus • High numbers atypical agranulocytes • Symptoms – Tired, achy, chronic sore throat, low fever • Runs course with rest © 2013 Pearson Education, Inc.

Platelets

• Cytoplasmic fragments of

megakaryocytes

• Blue-staining outer region; purple granules • Granules contain serotonin, Ca 2+ , enzymes, ADP, and platelet-derived growth factor (PDGF) – Act in clotting process • Normal = 150,000 – 400,000 platelets /ml of blood © 2013 Pearson Education, Inc.

Platelets

• Form temporary platelet plug that helps seal breaks in blood vessels • Circulating platelets kept inactive and mobile by nitric oxide (NO) and prostacyclin from endothelial cells lining blood vessels • Age quickly; degenerate in about 10 days • Formation regulated by

thrombopoietin

• Derive from

megakaryoblast

– Mitosis but no cytokinesis 

megakaryocyte

Figure 17.12 Formation of platelets.

Stem cell Developmental pathway Hematopoietic stem cell (hemocytoblast) Megakaryoblast (stage I megakaryocyte) Megakaryocyte (stage II/III) Megakaryocyte (stage IV) Platelets

Table 17.2 Summary of Formed Elements of the Blood (1 of 2)

Table 17.2 Summary of Formed Elements of the Blood (2 of 2)

Hemostasis

• Fast series of reactions for stoppage of bleeding • Requires

clotting factors,

Hemostasis: Vascular Spasm

• Vasoconstriction of damaged blood vessel • Triggers – Direct injury to vascular smooth muscle – Chemicals released by endothelial cells and platelets – Pain reflexes • Most effective in smaller blood vessels © 2013 Pearson Education, Inc.

Hemostasis: Platelet Plug Formation

• Positive feedback cycle • Damaged endothelium exposes collagen fibers – Platelets stick to collagen fibers via plasma protein von Willebrand factor – Swell, become spiked and sticky, and release chemical messengers • ADP causes more platelets to stick and release their contents • Serotonin and thromboxane A 2 spasm and platelet aggregation enhance vascular © 2013 Pearson Education, Inc.

Hemostasis: Coagulation

• Reinforces platelet plug with fibrin threads • Blood transformed from liquid to gel • Series of reactions using

clotting factors (procoagulants)

Figure 17.13 Events of hemostasis.

Collagen fibers Platelets Fibrin Step 1 Vascular spasm • Smooth muscle contracts, causing vasoconstriction.

Step 2 Platelet plug formation • Injury to lining of vessel exposes collagen fibers; platelets adhere.

• Platelets release chemicals that make nearby platelets sticky; platelet plug forms.

Step 3 Coagulation • Fibrin forms a mesh that traps red blood cells and platelets, forming the clot.

Slide 1

Figure 17.13 Events of hemostasis.

Step 1 Vascular spasm • Smooth muscle contracts, causing vasoconstriction.

Slide 2

Figure 17.13 Events of hemostasis.

Collagen fibers Step 1 Vascular spasm • Smooth muscle contracts, causing vasoconstriction.

Step 2 Platelet plug formation • Injury to lining of vessel exposes collagen fibers; platelets adhere.

Slide 3

Figure 17.13 Events of hemostasis.

Collagen fibers Platelets Step 1 Vascular spasm • Smooth muscle contracts, causing vasoconstriction.

Step 2 Platelet plug formation • Injury to lining of vessel exposes collagen fibers; platelets adhere.

• Platelets release chemicals that make nearby platelets sticky; platelet plug forms.

Slide 4

Figure 17.13 Events of hemostasis.

Collagen fibers Platelets Fibrin Step 1 Vascular spasm • Smooth muscle contracts, causing vasoconstriction.

Step 2 Platelet plug formation • Injury to lining of vessel exposes collagen fibers; platelets adhere.

• Platelets release chemicals that make nearby platelets sticky; platelet plug forms.

Step 3 Coagulation • Fibrin forms a mesh that traps red blood cells and platelets, forming the clot.

Slide 5

Coagulation: Overview

• Three phases of coagulation –

Prothrombin activator

formed in both intrinsic and extrinsic pathways –

Prothrombin

converted to enzyme

thrombin

– Thrombin catalyzes

fibrinogen



fibrin

Coagulation Phase 1: Two Pathways to Prothrombin Activator

• Initiated by either intrinsic or extrinsic pathway (usually both) – Triggered by tissue-damaging events – Involves a series of procoagulants – Each pathway cascades toward factor X • Factor X complexes with Ca 2+ , PF 3 , and factor V to form prothrombin activator © 2013 Pearson Education, Inc.

Coagulation Phase 1: Two Pathways to Prothrombin Activator

• Intrinsic pathway – Triggered by negatively charged surfaces (activated platelets, collagen, glass) – Uses factors present within blood (intrinsic) • Extrinsic pathway – Triggered by exposure to tissue factor (TF) or factor III (an extrinsic factor) – Bypasses several steps of intrinsic pathway, so faster © 2013 Pearson Education, Inc.

Coagulation Phase 2: Pathway to Thrombin

Coagulation Phase 3: Common Pathway to the Fibrin Mesh

• Thrombin converts soluble fibrinogen to fibrin • Fibrin strands form structural basis of clot • Fibrin causes plasma to become a gel-like trap for formed elements • Thrombin (with Ca 2+ ) activates factor XIII which: – Cross-links fibrin – Strengthens and stabilizes clot © 2013 Pearson Education, Inc.

Figure 17.14 The intrinsic and extrinsic pathways of blood clotting (coagulation). (1 of 2) Phase 1 Intrinsic pathway Vessel endothelium ruptures, exposing underlying tissues (e.g., collagen) Extrinsic pathway Tissue cell trauma exposes blood to Platelets cling and their surfaces provide sites for mobilization of factors Tissue factor (TF) XII Ca 2+ XII a XI VII XI a VII a IX Ca 2+ IX a PF 3 released by aggregated platelets VIII VIII a IX a /VIII a complex TF/VII a complex X X a Ca 2+ PF 3 Prothrombin activator V a V

Figure 17.14 The intrinsic and extrinsic pathways of blood clotting (coagulation). (2 of 2) Phase 2 Prothrombin (II) Thrombin (II a ) Phase 3 Fibrinogen (I) (soluble) Fibrin (insoluble polymer) Cross-linked fibrin mesh XIII a

Ca 2+ XIII

Figure 17.15 Scanning electron micrograph of erythrocytes trapped in a fibrin mesh.

Clot Retraction

• Stabilizes clot • Actin and myosin in platelets contract within 30 –60 minutes • Contraction pulls on fibrin strands, squeezing serum from clot • Draws ruptured blood vessel edges together © 2013 Pearson Education, Inc.

Vessel Repair

• Vessel is healing as clot retraction occurs • Platelet-derived growth factor (PDGF) stimulates division of smooth muscle cells and fibroblasts to rebuild blood vessel wall • Vascular endothelial growth factor (VEGF) stimulates endothelial cells to multiply and restore endothelial lining © 2013 Pearson Education, Inc.

Fibrinolysis

• • Removes unneeded clots after healing • Begins within two days; continues for several • Plasminogen in clot is converted to plasmin by tissue plasminogen activator (tPA), factor XII and thrombin

Plasmin

Factors Limiting Clot Growth or Formation

• Two mechanisms limit clot size – Swift removal and dilution of clotting factors – Inhibition of activated clotting factors • • Thrombin bound onto fibrin threads

Antithrombin III

Factors Preventing Undesirable Clotting

• Platelet adhesion is prevented by – Smooth endothelium of blood vessels prevents platelets from clinging – Antithrombic substances nitric oxide and prostacyclin secreted by endothelial cells – Vitamin E quinone acts as potent anticoagulant © 2013 Pearson Education, Inc.

Disorders of Hemostasis

• • •

Thromboembolic disorders

: undesirable clot formation

Bleeding disorders

: abnormalities that prevent normal clot formation

Disseminated intravascular coagulation (DIC)

Thromboembolic Conditions

•

Thrombus

: clot that develops and persists in

unbroken

blood vessel – May block circulation leading to tissue death •

Embolus

: thrombus freely floating in bloodstream •

Embolism

Anticoagulant Drugs

• •

Aspirin

– Antiprostaglandin that inhibits thromboxane A 2

Heparin

– Anticoagulant used clinically for pre- and postoperative cardiac care •

Warfarin

(Coumadin) – Used for those prone to atrial fibrillation – Interferes with action of vitamin K •

Dabigatran

Bleeding Disorders

•

Thrombocytopenia

: deficient number of circulating platelets –

Petechiae

appear due to spontaneous, widespread hemorrhage – Due to suppression or destruction of red bone marrow (e.g., malignancy, radiation, drugs) – Platelet count <50,000/μl is diagnostic – Treated with transfusion of concentrated platelets © 2013 Pearson Education, Inc.

Bleeding Disorders

• Impaired liver function – Inability to synthesize procoagulants – Causes include vitamin K deficiency, hepatitis, and cirrhosis – Impaired fat absorption and liver disease can also prevent liver from producing bile, impairing fat and vitamin K absorption © 2013 Pearson Education, Inc.

Bleeding Disorders

• Hemophilia includes several similar hereditary bleeding disorders – Hemophilia A: most common type (77% of all cases); factor VIII deficiency – Hemophilia B: factor IX deficiency – Hemophilia C: mild type; factor XI deficiency • Symptoms include prolonged bleeding, especially into joint cavities • Treated with plasma transfusions and injection of missing factors – Increased hepatitis and HIV risk © 2013 Pearson Education, Inc.

Disseminated Intravascular Coagulation (DIC)

• Clotting causes bleeding – Widespread clotting blocks intact blood vessels – Severe bleeding occurs because residual blood unable to clot • Occurs as pregnancy complication; in septicemia, or incompatible blood transfusions © 2013 Pearson Education, Inc.

Transfusions

• Whole-blood transfusions used when blood loss rapid and substantial • Packed red cells (plasma and WBCs removed) transfused to restore oxygen carrying capacity • Transfusion of incompatible blood can be fatal © 2013 Pearson Education, Inc.

Human Blood Groups

• RBC membranes bear 30 types of glycoprotein

antigens

– Anything perceived as foreign; generates an immune response – Promoters of agglutination; called

agglutinogens

• Mismatched transfused blood perceived as foreign – May be agglutinated and destroyed; can be fatal • Presence or absence of each antigen is used to classify blood cells into different groups © 2013 Pearson Education, Inc.

Blood Groups

ABO Blood Groups

• Types A, B, AB, and O • Based on presence or absence of two agglutinogens (A and B) on surface of RBCs • Blood may contain preformed anti-A or anti-B antibodies (

agglutinins

Table 17.4 ABO Blood Groups

Rh Blood Groups

• Anti-Rh antibodies not spontaneously formed in Rh – individuals – Anti-Rh antibodies form if Rh – receives Rh + blood, or Rh – individual mom carrying Rh + fetus • Second exposure to Rh + blood will result in typical transfusion reaction © 2013 Pearson Education, Inc.

Homeostatic Imbalance: Hemolytic Disease of the Newborn

• Also called

erythroblastosis fetalis

– Only occurs in Rh – mom with Rh + fetus • Rh – mom exposed to Rh + blood of fetus during delivery of first baby – baby healthy – Mother synthesizes anti-Rh antibodies • Second pregnancy – Mom's anti-Rh antibodies cross placenta and destroy RBCs of Rh + baby © 2013 Pearson Education, Inc.

Homeostatic Imbalance: Hemolytic Disease of the Newborn

• • Baby treated with prebirth transfusions and exchange transfusions after birth

RhoGAM

Transfusion Reactions

• Occur if mismatched blood infused • Donor's cells – Attacked by recipient's plasma agglutinins – Agglutinate and clog small vessels – Rupture and release hemoglobin into bloodstream • Result in – Diminished oxygen-carrying capacity – Diminished blood flow beyond blocked vessels – Hemoglobin in kidney tubules  renal failure © 2013 Pearson Education, Inc.

Transfusion Reactions

Transfusions

• Type O

universal donor

– No A or B antigens • Type AB

universal recipient

– No anti-A or anti-B antibodies • • Misleading - other agglutinogens cause transfusion reactions

Autologous transfusions

Before Transfusion

•

Blood typing

– Mixing RBCs with antibodies against its agglutinogen(s) causes clumping of RBCs – Done for ABO and for Rh factor •

Cross matching

Figure 17.16 Blood typing of ABO blood types.

Blood being tested Anti-A Serum Anti-B Type AB sera) (contains agglutinogens A and B; agglutinates with both RBCs Type A (contains agglutinogen A; agglutinates with anti-A) Type B (contains agglutinogen B; agglutinates with anti-B)

Type O serum) (contains no agglutinogens; does not agglutinate with either

Restoring Blood Volume

• Death from shock may result from low blood volume • Volume must be replaced immediately with – Normal saline or multiple-electrolyte solution (Ringer's solution) that mimics plasma electrolyte composition – Plasma expanders (e.g., purified human serum albumin, hetastarch, and dextran) • Mimic osmotic properties of albumin • More expensive and may cause significant complications © 2013 Pearson Education, Inc.

Diagnostic Blood Tests

• Differential WBC count • Prothrombin time and platelet counts assess hemostasis • • SMAC, a blood chemistry profile – liver and kidney disorders

Complete blood count

(

CBC

Developmental Aspects

• Fetal blood cells form in fetal yolk sac, liver, and spleen • Red bone marrow is primary hematopoietic area by seventh month • Blood cells develop from mesenchymal cells called blood islands • The fetus forms Hemoglobin F, which has higher affinity for O formed after birth 2 than hemoglobin A © 2013 Pearson Education, Inc.