1. Figure 4-1 The Polarity of Epithelial Cells
Cilia
Microvilli
Apical surface
Golgi apparatus
p. 116
Nucleus
Mitochondria
Basement membrane
Basolateral surfaces
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2. Figure 4-2 Cell Junctions
Interlocking junctional proteins
Tight junction
Tight junction
Adhesion belt
Terminal web
Spot desmosome
Adhesion belt
Gap junctions
Hemidesmosome
Embedded proteins (connexons)
Intermediate filaments
Clear layer
Basement membrane
Dense layer
Dense area
Cell adhesion molecules (CAMs)
p. 117
Proteoglycans
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3. Figure 4-2a Cell Junctions
Tight junction
Adhesion belt
Terminal web
Spot desmosome
Gap junctions
Hemidesmosome
This is a diagrammatic view of an epithelial cell, showing the major types of intercellular connections.
p. 117
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4. Figure 4-2b Cell Junctions
Interlocking junctional proteins
Tight junction
Terminal web
Adhesion belt
p. 117
A tight junction is formed by the fusion of the outer layers of two plasma membranes. Tight junctions prevent the diffusion of fluids and solutes between the cells. A continuous adhesion belt lies deep to the tight junction. This belt is tied to the microfilaments of the terminal web.
© 2015 Pearson Education, Inc. 4

5. Figure 4-2c Cell Junctions
Embedded proteins (connexons)
Gap junctions permit the free diffusion of ions and small molecules between two cells.
p. 117
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6. Figure 4-2d Cell Junctions
Intermediate filaments
Cell adhesion molecules (CAMs)
Dense area
Proteoglycans
A spot desmosome ties adjacent cells together.
p. 117
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7. Figure 4-2e Cell Junctions
Clear layer
Basement membrane
Dense layer
Hemidesmosomes attach a cell to extracellular structures, such as the protein fibers in the basement membrane.
p. 117
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8. Table 4-1 Classifying Epithelia
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9. Table 4-1 Classifying Epithelia
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10. Figure 4-4c Cuboidal and Transitional Epithelia
Transitional Epithelium
LOCATIONS: Urinary bladder; renal pelvis; ureters
FUNCTIONS: Permits expansion and recoil after stretching
Epithelium (relaxed)
Basement membrane
Connective tissue and smooth muscle layers
Empty bladder
LM  400
Epithelium (stretched)
Basement membrane
LM  400
Connective tissue and smooth muscle layers
Full bladder
LM  400
Urinary bladder
p. 121
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11. Figure 4-3a Squamous Epithelia
Simple Squamous Epithelium
LOCATIONS: Mesothelia lining ventral body cavities; endothelia lining heart and blood vessels; portions of kidney tubules (thin sections of nephron loops); inner lining of cornea; alveoli of lungs
FUNCTIONS: Reduces friction; controls vessel permeability; performs absorption and secretion
Cytoplasm
Nucleus
Connective tissue
LM  238
Lining of peritoneal cavity
p. 119
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12. Figure 4-3b Squamous Epithelia
Stratified Squamous Epithelium
LOCATIONS: Surface of skin; lining of mouth, throat, esophagus, rectum, anus, and vagina
FUNCTIONS: Provides physical protection against abrasion, pathogens, and chemical attack
Squamous superficial cells
Stem cells
Basement membrane
Connective tissue
Surface of tongue
LM  310
p. 119
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13. Figure 4-4a Cuboidal and Transitional Epithelia
Simple Cuboidal Epithelium
LOCATIONS: Glands; ducts; portions of kidney tubules; thyroid gland
Connective tissue
FUNCTIONS: Limited protection, secretion, absorption
Nucleus
Cuboidal cells
Basement membrane
Kidney tubule
LM  650
p. 121
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14. Figure 4-4b Cuboidal and Transitional Epithelia
Stratified Cuboidal Epithelium
LOCATIONS: Lining of some ducts (rare)
FUNCTIONS: Protection, secretion, absorption
Lumen of duct
Stratified cuboidal cells
Basement membrane
Nuclei
Connective tissue
Sweat gland duct
LM  500
p. 121
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15. Figure 4-4c Cuboidal and Transitional Epithelia
Transitional Epithelium
LOCATIONS: Urinary bladder; renal pelvis; ureters
FUNCTIONS: Permits expansion and recoil after stretching
Epithelium (relaxed)
Basement membrane
Connective tissue and smooth muscle layers
Empty bladder
LM  400
Epithelium (stretched)
Basement membrane
LM  400
Connective tissue and smooth muscle layers
Full bladder
LM  400
Urinary bladder
p. 121
© 2015 Pearson Education, Inc. 15

16. Figure 4-5a Columnar Epithelia
Simple Columnar Epithelium
LOCATIONS: Lining of stomach, intestine, gallbladder, uterine tubes, and collecting ducts of kidneys
Microvilli
Cytoplasm
FUNCTIONS: Protection, secretion, absorption
Nucleus
Basement membrane
Loose connective tissue
Intestinal lining
LM  350
p. 122
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17. Figure 4-5b Columnar Epithelia
Pseudostratified Ciliated Columnar Epithelium
LOCATIONS: Lining of nasal cavity, trachea, and bronchi; portions of male reproductive tract
Cilia
Cytoplasm
FUNCTIONS: Protection, secretion, move mucus with cilia
Nuclei
Basement membrane
Loose connective tissue
Trachea
LM  350
p. 122
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18. Figure 4-5c Columnar Epithelia
Stratified Columnar Epithelium
LOCATIONS: Small areas of the pharynx, epiglottis, anus, mammary glands, salivary gland ducts, and urethra
Loose connective tissue
Deeper basal cells
FUNCTION: Protection
Superficial columnar cells
Lumen
Lumen
Cytoplasm
Nuclei
Basement membrane
Salivary gland duct
LM  175
p. 122
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19. Figure 4-6 Modes of Glandular Secretion.
(a) Merocrine secretion
In merocrine secretion, the product is released from secretory
vesicles at the apical surface of the gland cell by exocytosis.
Secretory vesicle
Golgi apparatus
Nucleus
TEM × 3039
Salivary gland
(b) Apocrine secretion
Apocrine secretion involves the loss of apical cytoplasm. Inclusions, secretory vesicles, and other cytoplasmic components are shed in the process. The gland cell then grows and repairs itself before it releases additional secretions.
Mammary gland
Breaks down
Golgi apparatus
Hair
Secretion
Regrowth 1 2 3 4
Sebaceous gland
Hair follicle
(c) Holocrine secretion
Holocrine secretion occurs as superficial gland cells burst. Continued secretion involves the replacement of these cells through the mitotic divisions of underlying stem cells. 3
Cells burst, releasing cytoplasmic contents 2
Cells form secretory products and increase in size
p. 124 1
Cell division replaces lost cells
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Stem cell

20. Figure 4-6a Modes of Glandular Secretion.
(a) Merocrine secretion
In merocrine secretion, the product is released from secretory
vesicles at the apical surface of the gland cell by exocytosis.
Salivary gland
Secretory vesicle
Golgi apparatus
Mammary gland
Nucleus
TEM × 3039
Hair
Sebaceous gland
Hair follicle
p. 124
© 2015 Pearson Education, Inc.

21. Figure 4-6b Modes of Glandular Secretion.
Salivary gland
(b) Apocrine secretion
Apocrine secretion involves the loss of apical cytoplasm. Inclu- sions, secretory vesicles, and other cytoplasmic components are shed in the process. The gland cell then grows and repairs itself before it releases additional secretions.
Mammary gland
Breaks down
Golgi apparatus
Hair
Secretion
Regrowth 1 2 3 4
Sebaceous gland
Hair follicle
p. 124
© 2015 Pearson Education, Inc.

22. Figure 4-6c Modes of Glandular Secretion.
Salivary gland
(c) Holocrine secretion
Holocrine secretion occurs as superficial gland cells burst. Contin- ued secretion involves the replacement of these cells through the mitotic divisions of underlying stem cells.
Mammary gland 3
Cells burst, releasing cytoplasmic contents 2
Cells form secretory products and increase in size
Hair 1
Cell division replaces lost cells
Sebaceous gland
Stem cell
Hair follicle
p. 124
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23. Figure 4-7 A Structural Classification of Exocrine Glands
SIMPLE GLANDS
Duct
Gland cells
SIMPLE TUBULAR
SIMPLE COILED TUBULAR
SIMPLE BRANCHED TUBULAR
Examples:
Examples:
Examples:
• Intestinal glands
• Merocrine sweat
• Gastric glands
glands
• Mucous glands
of esophagus, tongue, duodenum
SIMPLE ALVEOLAR (ACINAR)
SIMPLE BRANCHED ALVEOLAR
Examples:
Examples:
• Not found in adult; a
• Sebaceous (oil)
p. 125
stage in development of simple branched glands
glands
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24. Figure 4-7 A Structural Classification of Exocrine Glands
COMPOUND GLANDS
COMPOUND TUBULAR
COMPOUND ALVEOLAR (ACINAR)
COMPOUND TUBULOALVEOLAR
Examples:
Examples:
Examples:
• Mucous glands (in mouth)
• Mammary glands
• Salivary glands
• Bulbo-urethral glands (in
• Glands of respiratory
male reproductive system)
passages
• Testes (seminiferous
tubules)
• Pancreas
p. 125
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25. Figure 4-8 The Cells and Fibers of Connective Tissue Proper
Reticular fibers
Mast cell
Melanocyte
Elastic
fibers
Fixed macrophage
Plasma cell
Free macrophage
Collagen fibers
Blood in vessel
Fibroblast
Adipocytes (fat cells)
Mesenchymal cell
Ground substance
Lymphocyte
p. 127
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26. Figure 4-10a Loose Connective Tissues.
Areolar Tissue
LOCATIONS: Within and deep to the dermis of skin, and covered by the epithelial lining of the digestive, respiratory, and urinary tracts;
between muscles; around joints,
blood vessels, and nerves
Fibrocytes
Macrophage
Collagen fibers
FUNCTIONS: Cushions organs; provides support but permits independent movement; phagocytic cells provide defense against pathogens
Mast cell
Elastic fibers
Areolar tissue from pleura
LM × 380 a
Areolar tissue
p. 130
© 2015 Pearson Education, Inc.

27. Figure 4-10a Adipose and Reticular Tissues
Adipose Tissue
LOCATIONS: Deep to the skin, especially at sides, buttocks, breasts; padding around eyes and kidneys
FUNCTIONS: Provides padding and cushions shocks; insulates (reduces heat loss); stores energy
Adipocytes (white adipose cells)
LM  300
Adipose tissue
p. 130
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28. Figure 4-10b Adipose and Reticular Tissues
LOCATIONS: Liver, kidney, spleen, lymph nodes, and bone marrow
FUNCTIONS: Provides supporting framework
Reticular fibers
Reticular tissue from liver
LM  375
Reticular Tissue
p. 130
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29. Figure 4-11a Dense Connective Tissues
Dense Regular Connective Tissue
LOCATIONS: Between skeletal muscles and skeleton (tendons and aponeuroses); between bones or stabilizing positions of internal organs (ligaments); covering skeletal muscles; deep fasciae
Collagen fibers
FUNCTIONS: Provides firm attachment; conducts pull of muscles; reduces friction between muscles; stabilizes relative positions of bones
Fibroblast nuclei
Tendon
LM  440
p. 132
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30. Figure 4-11b Dense Connective Tissues
Dense Irregular Connective Tissue
LOCATIONS: Capsules of visceral organs; periostea and perichondria; nerve and muscle sheaths; dermis
FUNCTIONS: Provides strength to resist forces applied from many directions; helps prevent overexpansion of organs such as the urinary bladder
Collagen fiber
bundles
Deep dermis
LM  111
p. 132
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31. Figure 4-11c Dense Connective Tissues
Elastic Tissue
LOCATIONS: Between vertebrae of the spinal column (ligamentum flavum and ligamentum nuchae); ligaments supporting penis; ligaments supporting transitional epithelia; in blood vessel walls
Elastic fibers
FUNCTIONS: Stabilizes positions of vertebrae and penis; cushions shocks; permits expansion and contraction of organs
Fibroblast nuclei
Elastic ligament
LM  887
p. 132
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32. Connective Tissues
p. 133
Copyright © 2009 Pearson Education, Inc., publishing as Pearson Benjamin Cummings

33. Figure 4-13a The Growth of Cartilage
Matrix
New matrix
Chondrocyte
Lacuna
Chondrocyte undergoes division within a lacuna surrounded by cartilage matrix.
As daughter cells secrete additional matrix, they move apart, expanding the cartilage from within.
Interstitial growth
p. 134
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34. Figure 4-13b The Growth of Cartilage
Fibroblast
Dividing stem cell
Perichondrium
New matrix
Chondroblasts
Immature chondrocyte
Older matrix
Mature chondrocyte
Cells in the cellular layer of the perichondrium differentiate into chondroblasts.
These immature chondroblasts secrete new matrix.
As the matrix enlarges, more chondroblasts are incorporated; they are replaced by divisions of stem cells in the perichondrium.
Appositional growth
p. 134
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35. Figure 4-14a Types of Cartilage
Hyaline Cartilage
LOCATIONS: Between tips of ribs and bones of sternum; covering bone surfaces at synovial joints; supporting larynx (voice box), trachea, and bronchi; forming part of nasal septum
FUNCTIONS: Provides stiff but somewhat flexible support; reduces friction between bony surfaces
Chondrocytes in lacunae
Matrix
LM  500
Hyaline cartilage
p. 135
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36. Figure 4-14b Types of Cartilage
Elastic Cartilage
LOCATIONS: Auricle of external ear; epiglottis; auditory canal; cuneiform cartilages of larynx
FUNCTIONS: Provides support, but tolerates distortion without damage and returns to original shape
Chondrocyte in lacuna
Elastic fibers in matrix
LM  358
Elastic cartilage p
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37. Figure 4-14c Types of Cartilage
Fibrocartilage
LOCATIONS: Pads within knee joint; between pubic bones of pelvis; intervertebral discs
FUNCTIONS: Resists compression; prevents bone- to-bone contact; limits movement
Chondrocytes in lacunae
Fibrous matrix
LM  400
Fibrocartilage
p. 135
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38. © 2015 Pearson Education, Inc.
Figure Bone
Fibrous layer
Canaliculi
Periosteum
Cellular layer
Osteocytes in lacunae
Matrix
Osteon
Central canal
Blood vessels
Osteon
LM  375
p. 136
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39. Table 4-2 A Comparison of Cartilage and Bone
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40. © 2015 Pearson Education, Inc.
Figure 4-16a Membranes
Mucous secretion
Epithelium
Lamina propria (areolar tissue)
Mucous membranes are coated with the secretions of mucous glands. These membranes line the digestive, respiratory, urinary, and reproductive tracts.
p. 138
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41. © 2015 Pearson Education, Inc.
Figure 4-16b Membranes
Transudate
Mesothelium
Areolar tissue
Serous membranes line the ventral body cavities (the peritoneal, pleural, and pericardial cavities).
p. 138
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42. © 2015 Pearson Education, Inc.
Figure 4-16d Membranes
Articular (hyaline) tissue
Synovial fluid
Capsule
Capillary
Adipocytes
Areolar tissue
Synovial membrane
Epithelium
Bone
Synovial membranes line joint cavities and produce the fluid within the joint.
p. 138
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43. © 2015 Pearson Education, Inc.
Figure 4-16c Membranes
Epithelium
Areolar tissue
Dense irregular connective tissue
The cutaneous membrane, or skin, covers the outer surface of the body.
p. 138
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44. © 2015 Pearson Education, Inc.
Figure The Fasciae
Body wall
Connective Tissue Framework of Body
Body cavity
Superficial Fascia
• Between skin and
underlying organs
• Areolar tissue and
adipose tissue
• Also known as
subcutaneous layer or hypodermis
Skin
Deep Fascia
• Forms a strong, fibrous
internal framework
• Dense connective tissue
• Bound to capsules,
tendons, and ligaments
Subserous Fascia
• Between serous
membranes and deep fascia
• Areolar tissue
Rib
Serous membrane
Cutaneous membrane
p. 140
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