LAB 3 Tissues 2022 PDF

Summary

This document is a lab manual for histology, focusing on different tissue types including epithelial, connective, muscle, and nervous tissues. It outlines the characteristics, functions, and locations of these tissues, along with practical instructions for observing tissue samples under a microscope.

Full Transcript

LAB 3 HISTOLOGY

I TISSUES

At the end of this exercise, you should be able to:

1. Identify microscopic samples of epithelial, connective, muscle and nervous tissue, and
the components of each tissue type.
2. Describe the general characteristics of each of the tissues, including structure, function,
and location.
3. Identify at least two locations in the body for each tissue type.

Lab introduced you to the general structure and function of the parts of the cell. Groups
of similar cells that work together to carry out a specialized function are called tissues. To
perform specific body functions, various tissue types are organized into organs. The
arrangement of these tissues within an organ determines the organ's structure and function.
Tissues are divided into four major categories based on cell arrangement, shape, and
function: epithelial, muscular, connective and nervous.

Histology is the microscopic study of tissue structure and function. When viewing slides it
is important that you begin by scanning each slide at low power (4x) to examine the entire
tissue. A slide may have only one tissue on it, or may have several tissues, of which you
want to see only one. Once you have located the tissue you want to view, increase the
magnification to medium (10x) then to high power (40x) to observe individual cells. At high
power, rotate the fine focus knob back and forth an eighth of a turn to see the details of
finer structures, like cilia and cell membranes.

It is strongly suggested that you make your own sketches of the slides, and include any
features in bold or other structures that will assist with subsequent identification. You
should include at least two locations for each of these tissues in the tables below.

PART A: EPITHELIAL TISSUE

Epithelial tissues cover external body surfaces, line cavities and hollow organs, and form
glands. The functions of epithelial tissue can include protection, absorption, secretion,
filtration, and excretion. Some characteristics that distinguish them from other tissues are:
They do not have a direct blood supply, but get their nutrients by diffusion from
blood vessels located in the underlying connective tissue.
The tissue always attaches to the basement membrane (the basal surface) and
always has one free surface (the apical surface), where cells are exposed to the
lumen.
The cells can regenerate by mitosis.
May produce specialized secretions.

1. Covering and Lining Epithelia

Epithelial cells are classified based on whether the cells are arranged in layers and the
shape of the cells in the surface/apical layer. A single layer of cells is a simple epithelium.
Two or more layers of cells are called stratified epithelium. In a stratified epithelium,
only the cells of the basal layer attach to the basement membrane while the cells of the
apical layer face the lumen. Pseudostratified epithelium is a modified simple epithelium
– all the cells attach to the basement membrane (farthest from the lumen) though not all
reach the lumen. Flattened, irregular cells are squamous. Cuboidal cells are cube-shaped;
the height and width are about equal. Columnar cells are taller than they are wide.

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Figure 3.1 Cell shapes and arrangement of layers of epithelial tissues. From Tortora and
Derrickson, Principles of Anatomy and Physiology, 14th Ed., Copyright © 2014 by Biological Sciences Textbooks, Inc. and Bryan
Derrickson. This material is used by permission of John Wiley & Sons, Inc.

The slides in your slide box are numbered in the same order as the information in the lab
manual. Observe each of the slides listed below. Unless otherwise indicated, use the 40x
objective lens to see individual cells.

Pay attention to which organelles are visible, the cell shape, and any other structures
indicated in the list for you to find.

In general, the nucleus of a cell stains darker than the cytoplasm. Since it can sometimes
be difficult to see plasma membranes, you should practice scanning for the shape of the
nucleus to help you identify the shape of the cell.

Once you have found a representative section on your slide, showing cells that resemble
those in photomicrographs, sketch what you see and label as many structures as possible.

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 Description: A single layer of flattened cells with a central nucleus
1. simple squamous (nucleus looks flattened and oval from side, oval or round from
epithelium above).

slide may be called Locations: Lines blood and lymphatic vessels, alveoli, glomerular
cheek cell capsule, inner surface of tympanic membrane, and forms serous
membranes.

Functions: thinness allows passage of materials by diffusion and
filtration in areas where protection is not important; secretes
serous fluid within serous membranes.

simple squamous drawing

Figure 3.2 Whole mount slide of simple
squamous epithelium, magnified 240x.
From Tortora and Derrickson, Principles of Anatomy and
Physiology, 12th Ed., Copyright © 2009 by Biological Sciences
Textbooks, Inc. and Bryan Derrickson. This material is used by
permission of John Wiley & Sons, Inc.

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 Description: A single layer of cube-shaped cells with a large,
2. simple cuboidal central nucleus.
epithelium

slide may be called Locations:
kidney slide

Functions:

simple cuboidal drawing

Figure 3.3 Simple cuboidal
epithelium, magnified 100x.
From Tortora and Derrickson, Principles of
Anatomy and Physiology, 14th Ed., Copyright ©
2014 by Biological Sciences Textbooks, Inc. and
Bryan Derrickson. This material is used by
permission of John Wiley & Sons, Inc.

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 Description: A single layer of cells which are taller than they are
3. simple columnar wide, with an oval-shaped nucleus found in the lower half of cell.
epithelium Find goblet cells, may see microvilli.

Locations:

Functions:

simple columnar drawing

Figure 3.4 Simple columnar epithelium
showing goblet cells and microvilli,
magnified 675x. From Tortora and Derrickson,
Principles of Anatomy and Physiology, 11th Ed., Copyright ©
2006 by Biological Sciences Textbooks, Inc. and Bryan
Derrickson. This material is used by permission of John Wiley
& Sons, Inc.

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 Description: As in simple ciliated columnar. Not all cells reach the
4. pseudostratified lumen; nuclei are seen at different levels in the cells. Look for
ciliated columnar goblet cells and cilia.
epithelium
Locations:

Functions:

pseudostratified ciliated columnar drawing

Figure 3.5 Pseudostratified ciliated
columnar epithelium, magnified 500x.
From Tortora and Derrickson, Principles of Anatomy and
Physiology, 11th Ed., Copyright © 2006 by Biological Sciences
Textbooks, Inc. and Bryan Derrickson. This material is used
by permission of John Wiley & Sons, Inc.

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 Description: Several layers of cells. Find squamous at the apical
5. stratified surface and cuboidal or columnar at basal surface of the tissue.
squamous
epithelium
Locations:
see slide of vagina

Functions:

stratified squamous drawing

Figure 3.6 Stratified squamous
epithelium, magnified 200x. From Tortora
and Derrickson, Principles of Anatomy and Physiology, 11th
Ed., Copyright © 2006 by Biological Sciences Textbooks,
Inc. and Bryan Derrickson. This material is used by
permission of John Wiley & Sons, Inc.

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 Description: When relaxed, cells at the apical surface look large and
6. rounded. Not all cells reach the apical or basal surface. Cells can
be a variety of shapes and sizes.

Locations:
slide may be called
ureter slide

Functions:

drawing

Figure 3.7 , magnified
400x. From Tortora and Derrickson, Principles of
Anatomy and Physiology, 14th Ed., Copyright © 2014 by
Biological Sciences Textbooks, Inc. and Bryan
Derrickson. This material is used by permission of John
Wiley & Sons, Inc.

Compare the functions of simple epithelium with that of stratified epithelium.

Name two types of epithelial tissues that have goblet cells.

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2. Glandular Epithelia

Many epithelial tissues contain single-celled or multicellular glands that produce secretions.
If the secretions are released into the surrounding interstitial tissue and distributed by the
blood stream, the glands are called endocrine glands. Endocrine glands such as the
thyroid and pituitary secrete hormones, and will be covered extensively in Biol 1191. If
the secretions are released via ducts onto an epithelial surface, the gland is considered to
be an exocrine gland. Examples of exocrine secretions are milk, sebum and the enzymes
in the digestive system.

The unicellular exocrine gland that produces mucus was seen in the slide of
pseudostratified ciliated columnar epithelium (goblet cells). Identifying multicellular
glands on a slide can be complicated by the angle of the section taken. In many cases the
lumen of the duct is not visible in the center of the tubule or at the epithelial surface. Look
for groupings of cells that are cuboidal, short columnar or pizza-shaped with a round
nucleus.

Description: Darker purple clusters of cells (acini) make up the
7. pancreas majority of the pancreas. The ducts are not usually visible. Light
pink areas are connective tissue and blood vessels. The larger
group of lighter purple cells (in inset photo) is an endocrine islet.
Location:

Function:

pancreatic acini and islets drawing

Figure 3.8 Pancreas showing islets and
acini, inset image magnified 200x.
From Tortora and Derrickson, Principles of Anatomy and
Physiology, 14th Ed., Copyright © 2014 by Biological Sciences
Textbooks, Inc. and Bryan Derrickson. This material is used
by permission of John Wiley & Sons, Inc.

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 Description: Prominent ducts with visible lumen and acini.
8. salivary gland Appearance of acini varies with type of salivary gland (serous fluid
or mucus secreting).

Location:

Function:

salivary gland drawing

Figure 3.9 Submandibular salivary
gland showing mucous acini on right
and serous acini on left, magnified
350x. From Tortora and Derrickson, Principles of
Anatomy and Physiology, 11th Ed., Copyright © 2006 by
Biological Sciences Textbooks, Inc. and Bryan Derrickson.
This material is used by permission of John Wiley & Sons,
Inc.

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 Description: Located beside the hair follicle. Acinar cells are tear
9a. sebaceous drop in shape. Lumen very narrow, if visible.
gland
(on hairy skin slide)
Location:

Function:

sebaceous gland drawing

Figure 3.10 Hair, hair follicle and
associated sebaceous gland, magnified
60x. From Tortora and Derrickson, Principles of Anatomy
and Physiology, 14th Ed., Copyright © 2014 by Biological
Sciences Textbooks, Inc. and Bryan Derrickson. This material
is used by permission of John Wiley & Sons, Inc.

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 Description: Are coiled, tubular glands located in the deep dermis
9b. sudoriferous or upper subcutaneous region. Lumen can be seen in the coiled
gland regions, rarely seen leading to the surface.
(on hairy skin slide)
Location:

Function:

Sudoriferous gland drawing

Figure 3.11 Cross section through
the secretory portion of a sweat
gland, magnified 400x. From Tortora and
Derrickson, Principles of Anatomy and Physiology, 14th
Ed., Copyright © 2014 by Biological Sciences
Textbooks, Inc. and Bryan Derrickson. This material is
used by permission of John Wiley & Sons, Inc.

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PART B: CONNECTIVE TISSUE

The most common functions of connective tissues are to protect, support or bind together
other tissues. They also insulate, transport, and act to store energy as fat. The
characteristics of connective tissues are:
A non-living extracellular matrix produced by the cells of the connective tissue.
Have many types of cells that are scattered throughout the tissue.
Most are highly vascularized.
The extracellular matrix between the cells consists of two major components:
1) A ground substance that may be fluid, semi-fluid, gelatinous or very hard.
2) A combination of three different types of fibers, whose function is to strengthen and
support the tissue.

Collagen fibers often occur in parallel bundles, adding strength but not stiffness. Collagen
fibers are found in bone, cartilage, tendons and ligaments. Elastic fibers are strong, yet
can be stretched up to 150x their relaxed length without breaking. Elastic fibers are found
in skin, blood vessel walls and in the lungs. Reticular fibers form a branching network,
providing support and strength. They form the framework for many soft organs like the
spleen and lymph nodes, and form part of the basement membranes of epithelial tissues.

Figure 3.12 Representative cells and fibers present in connective tissues. From Tortora
and Derrickson, Principles of Anatomy and Physiology, 14th Ed., Copyright © 2014 by Biological Sciences Textbooks, Inc. and Bryan
Derrickson. This material is used by permission of John Wiley & Sons, Inc.

When observing connective tissue slides, all of the material on the slide is the tissue you
want to see, except for the hyaline cartilage slide. Scan the whole slide at 4x and 10x to
find a clear view, then focus at 40x.

Use the arrangement and size of the fibers, the shape and placement of the cells within the
ground substance, and the shape of the nucleus when identifying each type of connective
tissue.

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 Description: Has all three types of fibers and many different types
10. areolar of cells, with a loose, irregular arrangement.
connective tissue

Locations:

Functions:

areolar drawing

Figure 3.13 Areolar connective tissue,
magnified 300x. From Tortora and Derrickson,
Principles of Anatomy and Physiology, 11th Ed., Copyright ©
2006 by Biological Sciences Textbooks, Inc. and Bryan
Derrickson. This material is used by permission of John
Wiley & Sons, Inc.

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 Description: Nucleus and cytoplasm are displaced peripherally due
11. adipose to a large internal fat droplet. Matrix is sparse and the cells are
connective tissue closely packed.

Locations:

Functions:

adipose drawing

Figure 3.14 Adipose tissue,
magnified 200x. From Tortora and Derrickson,
Principles of Anatomy and Physiology, 14th Ed., Copyright
© 2014 by Biological Sciences Textbooks, Inc. and Bryan
Derrickson. This material is used by permission of John
Wiley & Sons, Inc.

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 Description: A network of dark reticular fibers with many cells
12. reticular containing small, round nuclei.
connective tissue

Locations:

Functions:

reticular drawing

Figure 3.15 Reticular connective
tissue, magnified 225x. From Tortora and
Derrickson, Principles of Anatomy and Physiology, 11th Ed.,
Copyright © 2006 by Biological Sciences Textbooks, Inc. and
Bryan Derrickson. This material is used by permission of
John Wiley & Sons, Inc.

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 Description: Wavy bundles of parallel collagen fibers. Note the
13. dense regular darkly stained cells between bundles of light pink fibers.
connective tissue

slide may be called Locations:
tendon

Functions:

dense regular drawing

Figure 3.16 Dense regular connective
tissue, magnified 250x. From Tortora and
Derrickson, Principles of Anatomy and Physiology, 11th Ed.,
Copyright © 2006 by Biological Sciences Textbooks, Inc.
and Bryan Derrickson. This material is used by permission
of John Wiley & Sons, Inc.

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 Description: Sparse numbers of chondrocytes lie in lacunae. The
14. hyaline matrix is made up of fine collagen fibers that are not visible.
cartilage

Locations:

Functions:

hyaline drawing

Figure 3.17 Hyaline cartilage,
magnified 200x. From Tortora and
Derrickson, Principles of Anatomy and Physiology, 14th
Ed., Copyright © 2014 by Biological Sciences
Textbooks, Inc. and Bryan Derrickson. This material
is used by permission of John Wiley & Sons, Inc.

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 Description: The matrix (collagen fibers and mineral salts) is
15. bone organized into layers called lamellae. Osteocytes sit in lacunae
that are connected by canaliculi. Best seen using the 10x
objective lens.
Locations:

Functions:

compact bone at 10x drawing

Figure 3.18 Compact bone,
magnified 550x. From Tortora and Derrickson,
Principles of Anatomy and Physiology, 11th Ed., Copyright
© 2006 by Biological Sciences Textbooks, Inc. and Bryan
Derrickson. This material is used by permission of John
Wiley & Sons, Inc.

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 Description: Cells are found in a fluid matrix (plasma). Fibers are
16. blood smear observed only during clotting. Find nucleated white blood cells
(leukocytes), red blood cells (erythrocytes) which lack a
nucleus, and platelets (thrombocytes).

Locations:

Functions:

erythrocytes, leukocytes, platelets
drawing

Figure 3.19 Blood, magnified 1230x.
From Tortora and Derrickson, Principles of Anatomy and
Physiology, 11th Ed., Copyright © 2006 by Biological
Sciences Textbooks, Inc. and Bryan Derrickson. This
material is used by permission of John Wiley & Sons, Inc.

How do connective tissues differ from epithelial tissues?

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PART C: MUSCULAR TISSUE

Muscle tissue contracts to provide body movements, to pump blood, and to control
movement of materials through the viscera.

The skeletal and smooth muscle slides may have both longitudinal and cross section
samples of the cells you are looking for. Be sure you are observing the longitudinal views.
Scan the slides to find the view which best shows the structures listed below.

The cardiac muscle slide has been cut from a section of curved tissue. Find an area of the
tissue where the cells are large and close together to see the identifying structures.

Figure 3.20 Microscopic appearance of the three types of muscle tissues. From Tortora
and Derrickson, Principles of Anatomy and Physiology, 11th Ed., Copyright © 2006 by Biological Sciences Textbooks, Inc. and Bryan
Derrickson. This material is used by permission of John Wiley & Sons, Inc.

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 Description: Long, cylindrical, striated, multinucleate muscle
17. skeletal muscle fibers. Nuclei are located on the periphery of the cells. Considered
to be voluntary.

Locations:

Functions:

skeletal muscle fibers drawing

Figure 3.21 Skeletal muscle tissue,
magnified 400x. From Tortora and Derrickson,
Principles of Anatomy and Physiology, 11th Ed., Copyright ©
2006 by Biological Sciences Textbooks, Inc. and Bryan
Derrickson. This material is used by permission of John
Wiley & Sons, Inc.

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 Description: Short, branched cells that typically have a single,
18. cardiac muscle centrally located nucleus. Have intercalated discs and
striations. Considered to be involuntary.

slide may be called Location:
intercalated disc

Functions:

cardiac muscle drawing

Figure 3.22 Cardiac muscle tissue,
magnified 600x. From Tortora and Derrickson,
Principles of Anatomy and Physiology, 11th Ed., Copyright
© 2006 by Biological Sciences Textbooks, Inc. and Bryan
Derrickson. This material is used by permission of John
Wiley & Sons, Inc.

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 Description: Short, spindle-shaped cells with a single, centrally
19. smooth muscle located nucleus. Considered to be involuntary.

Locations:

Functions:

smooth muscle drawing

Figure 3.23 Smooth muscle tissue, magnified 350x. From Tortora and Derrickson, Principles of
Anatomy and Physiology, 11th Ed., Copyright © 2006 by Biological Sciences Textbooks, Inc. and Bryan Derrickson. This material is
used by permission of John Wiley & Sons, Inc. Smooth muscle fiber, magnified 500x, from Tortora and
Derrickson, Principles of Anatomy and Physiology, 14th Ed., Copyright © 2014 by Biological Sciences Textbooks, Inc. and Bryan
Derrickson. This material is used by permission of John Wiley & Sons, Inc.

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How are smooth muscle cells and skeletal muscle fibers similar to each other? How are they
different?

SIMILARITIES DIFFERENCES

smooth
+
skeletal

How are skeletal muscle fibers similar to cardiac muscle cells? How are they different?

SIMILARITIES DIFFERENCES

cardiac
+
skeletal

What is the function of intercalated discs?

PART D: NERVOUS TISSUE

Nervous tissue consists of cells that can convert chemical or mechanical stimuli to electrical
signals (neurons), and cells with important support functions (neuroglia). Neurons have
three basic parts – a cell body containing a nucleus and other organelles, dendrites and
axons. On most slides, it is difficult to distinguish between axons and dendrites, though
axons may appear thicker.

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 Description: Large cell body with multiple extensions.
20. neurons

Locations:

Functions:

Description: Much smaller and more numerous than neurons.
neuroglia

Locations:

Functions:

neurons, neuroglia drawing

Figure 3.24 Neuron from spinal cord
and glial cells, magnified 430x. From
Tortora and Derrickson, Principles of Anatomy and
Physiology, 11th Ed., Copyright © 2006 by Biological
Sciences Textbooks, Inc. and Bryan Derrickson. This
material is used by permission of John Wiley & Sons, Inc.

What are the basic functions of nervous tissue?

How is nervous tissue involved in maintaining homeostasis?

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II THE INTEGUMENTARY SYSTEM

At the end of this exercise, you should be able to:

1. Discuss the functions of the integumentary system.
2. Identify and discuss the functions of the epidermis, the dermis and the hypodermis.
3. Identify and describe the functions of the accessory structures of the skin.
4. Differentiate between apocrine and eccrine sweat glands, and distinguish between
sudoriferous and sebaceous glands.

The integumentary system consists of the skin and its accessory structures – glands,
nails, hair, muscles and nerves. It is involved in protection against mechanical stress,
regulates water and heat loss, and is the site of Vitamin D synthesis.

The integument has two distinct regions. A superficial epidermis, composed of stratified
squamous epithelium, and a deeper dermis, composed of a layer of connective tissue. The
hypodermis or subcutaneous layer below the dermis is not part of the skin, but will be
studied here.

The epidermis is made of keratinized stratified squamous epithelium (non-keratinized
stratified squamous was studied earlier). In thick-skinned areas like the palmar and
plantar surfaces there are five layers in the epidermis: stratum corneum,
stratum lucidum, stratum granulosum, stratum spinosum and stratum basale.
In thin-skinned areas, the stratum lucidum is not present.

The dermis has finger-like projections, the dermal papillae, attaching it to the
epidermis. Numerous collagen and elastic fibers attach the dermis to the subcutaneous
layer. Unlike the epidermis, the dermis is highly vascularized.

A number of cutaneous sensory receptors are found in the dermis. When stimulated by
environmental changes (a touch, cold temperature, or a pinch) they transmit messages to
the brain (CNS) for interpretation.

The hypodermis attaches the dermis to the underlying structures. It is composed primarily
of adipose and areolar connective tissue, contains large blood vessels that supply
the dermis, and stores fat.

A variety of accessory structures, such as finger and toe nails, sweat glands and hair, are
found in the skin. Hair and hair follicles are derived from the stratum basale but can
extend from the surface of the skin to project into the dermis and hypodermis regions.
Arrector muscle of the hair (arrector pili muscle) attached to the hair follicles cause the
hairs to stand upright.

Several exocrine glands, which are also epidermal in origin, are found in the skin.
Sebaceous glands produce oil and are connected to the hair follicles, while sudoriferous
glands produce sweat.

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Identify the following structures on the skin models, and label Figure 3.25.

LAYER/STRUCTURE DESCRIPTION FUNCTION

epidermis

stratum corneum outermost layer,
undergoes exfoliation

stratum lucidum

stratum granulosum

stratum spinosum

stratum basale next to basement
membrane, single layer of
cuboidal or columnar cells

dermis

dermal papillae

tactile corpuscle/ detect the onset of the
Meissner corpuscle sensation of touch and
low frequency vibration

detect high frequency
lamellar corpuscle/ vibrations
Pacinian corpuscle

subcutaneous layer

hair follicle

hair

arrector muscle of the hair
(arrector pili muscle)

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 LAYER/STRUCTURE DESCRIPTION FUNCTION

sebaceous glands connected to hair follicles

sudoriferous glands

eccrine

apocrine
axillary and genital areas

Figure 3.25 Sectional view of the Figure 3.26 Layers of the epidermis
skin and subcutaneous layer. From of thick skin. From Tortora and Derrickson,
Tortora and Derrickson, Principles of Anatomy and Principles of Anatomy and Physiology, 14th Ed.,
Physiology, 14th Ed., Copyright © 2014 by Biological Copyright ©2014 by Biological Sciences Textbooks, Inc.,
Sciences Textbooks, Inc. and Bryan Derrickson. This and Bryan Derrickson. This material is used by
material is used by permission of John Wiley & Sons, Inc. permission of John Wiley & Sons, Inc.

3-29
1. Observe the slide of thick skin (palm or sole of foot) on the side bench. Using the 4x
objective lens scan the slide, from superficial to deep, and observe the epidermis, dermis
and subcutaneous regions. The epidermis typically stains darker than the dermis. Dermal
papillae can be seen at the junction between the epidermis and dermis. The dermis is a
mass of connective tissue and large blood vessels. Your slide may not show the hypodermis,
deep to the dermis.

At 10x and 40x, observe the layers of the epidermis. The stratum corneum of thick skin is
made of many layers of darkly stained, dead, anucleate, flattened, keratinocytes. The
stratum lucidum appears as a pale layer, sandwiched between the corneum and darker
stained granulosum. Deep to the stratum granulosum is the stratum spinosum and the
stratum basale. The stratum basale is a single row of columnar or cuboidal keratinocytes.

Sketch and label the slide of thick skin at 4x or 10x. Estimate the thickness of the stratum
corneum of thick skin, in millimeters. Use the 10x objective lens. __________ mm.

slide of thick skin drawing

Most of the cells forming the epidermis are keratinocytes. Where would you expect to find
the thinnest keratinized epidermis?

Give two functions of keratinocytes.

What is the function of the capillary networks in the dermis?

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2. Observe the slide of hairy skin on the side bench. Scan the slide with the low power
objective lens to see the three regions of the skin and the dermal papillae. On this slide,
only the stratum corneum and stratum basale are easily identified. Estimate the thickness
(in millimeters) of the corneum layer using the 10x lens. __________ mm.

Identify the hairs and hair follicles that sit at an angle to the skin surface. Depending on
the angle of the section, not all follicles or hairs appear to be connected to the surface.
Notice that the cells of the hair follicles stain the same colour as the epidermis, darker than
the dermis.

Find a hair follicle on your slide that has an arrector pili muscle. What type of muscle tissue
are the arrector pili made of? You may need to switch to the 40x objective lens to identify
the muscle cells.

Find sebaceous (oil) glands connected to the hair follicles, approximately ⅔ of the way up
the follicle. Using the 40x objective lens, note the round nuclei and irregularly shaped cells
of the gland. Are the lumens of the acinar glands visible?

There are two types of sudoriferous (sweat) glands. Your slide likely contains only eccrine
sweat glands, commonly seen as a cross section of coiled tubules at about the same height
as the base of the hair follicles. The duct of the gland and the pore opening at the skin
surface are not usually visible. Apocrine sweat glands are found mainly in the axillary and
genital areas, and can be seen on the skin model.

Sketch and label the slide of hairy skin at 4x or 10x. Include as many structures from the
list on page 3-29 as possible.

slide of hairy skin drawing

What regions of the body do not have hair?

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3. Observe the slide of pigmented skin on the side bench. The brown keratinocytes visible
in this slide show an accumulation of the pigment melanin in their cytoplasm. Melanin is
produced by melanocytes scattered throughout the stratum basale and is transferred to
other cells in the epidermis.

Which layers of the epidermis have accumulations of melanin in their cells?

What is the function of melanin in the skin?

The presence of a second pigment, carotene, may also influence skin colour. What is the
origin and function of carotene in the stratum corneum?

As a review, compare and contrast keratinized (e.g. skin slide) and non-keratinized (e.g.
vagina slide) stratified squamous epithelial tissue with respect to structure and function.

STRUCTURE FUNCTION

keratinized

non-keratinized

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