Basic Tissue - Chapter 8 PDF

Summary

This document provides an overview of basic tissue, cells, and their organization in the human body. Components include cells, tissues, organs, and body systems. It's a good introduction to the topic and seems to be part of a larger document.

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CELL: Smallest living unit of organization:
Epithelial cell, neuron, myofiber, chondrocyte, fibroblast,
erythrocyte, macrophage, sperm
TISSUE: Collection of similarly specialized cells: Epithelium,
nervous tissue, muscle, cartilage, bone, blood
ORGAN: Independent body part formed from tissue: Skin, brain,
heart, liver
SYSTEM: Organs functioning together:
Central nervous system, respiratory system, immune system,
cardiovascular system

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▪ Epithelium is avascular
▪ Cellular nutrition is obtained by
diffusion from the adjoining
connective tissue
▪ It serves to protect
▪ The basement membrane is
located between most
epithelium and deeper
connective tissue
▪ Produced by both the
epithelium and the adjoining
connective tissue.

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 Figure 7-5

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▪ Epithelium can be classified into two main categories based on its
arrangement into layers of cells: simple or stratified.
▪ The further classification of tissue involves different types of
epithelial cells according to cellular shape
▪ simple squamous
▪ simple cuboidal
▪ simple columnar

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▪ Simple epithelium consists of a single layer of epithelial cells.

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Simple squamous epithelium consists of flattened platelike epithelial cells, or
squames, lining blood and lymphatic vessels, heart, and serous cavities as well as
interfaces in the lungs and kidneys.

Applegate EJ. The Anatomy and Physiology Learning System, ed 3. Elsevier, 2006

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Simple cuboidal epithelium
consists of cube-shaped cells
that line the ducts of various
glands, such as certain ducts of
the salivary glands.

Simple columnar epithelium
consists of rectangular or tall
cells, such as in the lining of
other salivary gland ducts, as
well as the inner enamel
epithelium, whose cells become
enamel-forming ameloblasts.

**Remember IEE from Chapter
6?
Applegate EJ. The Anatomy and Physiology Learning System , ed 3. Elsevier, 2006

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▪ Simple collumnar cells

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PSEUDOSTRATIFIED COLUMNAR
EPITHELIUM: NASAL CAVITY

Figure 8-2

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 https://o.quizlet.com/2c7wxmpvd99UWxlJYD2oyQ_b.png

Figure 8-7

Most epithelium in the body is stratified
squamous epithelium, which includes the
superficial layer of the skin and oral mucosa.
Applegate EJ. The Anatomy and Physiology Learning System, ed 3. Elsevier, 2006

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▪ Interdigitation of the
outer epithelium with the
deeper connective
tissue, having a
basement membrane
between them, appears
on two-dimensional
microscopic section as
the rete ridges (or rete
pegs).

Figure 8-7

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 Figure 8-1B

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▪ The epidermis overlies a basement membrane and the
adjoining deeper layers of connective tissue (dermis and
hypodermis, respectively.
▪ The skin has varying degrees of keratinization depending on the
region of the body.

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▪ As discussed earlier, the
basement membrane is
a thin, acellular structure
always located between
any form of epithelium
and its underlying
connective tissue, as
noted in both the skin
and oral mucosa.

Figure 8-4

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 Figure 8-4

The basement membrane consists of
two layers: basal lamina and reticular
lamina.
▪ The superficial layer of the
basement membrane is the
basal lamina, which is
produced by the epithelium.

Figure 8-4

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▪ The basal lamina
consists of two sub-
layers microscopically:
lamina lucida is a clear
layer that is closer to the
epithelium, and lamina
densa is a dense layer
that is closer to the
connective tissue.

Figure 8-4

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▪ The deeper layer of the
basement membrane is
usually the reticular
lamina.
▪ It consists of collagen
fibers and reticular fibers
produced and secreted
by the underlying
connective tissue.

Figure 8-4

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SOMITES

Figure 3-12

Connective tissue is derived from the somites during
prenatal development.
Differentiated mesoderm gives rise to the somites that will
give rise to muscle tissue. Somites are located on the sides
of the developing central nervous system.
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 Figure 8-5B
A fibroblast is a type of cell that contributes to the
formation of connective tissue
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▪ Innermost layer of
tissue.
▪ Lies beneath the
epidermis and
dermis

Figure 8-7

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▪ Adipose connective tissue is a fatty tissue
that is found beneath the skin, around organs
and various joints, and in regions of the oral
cavity.

National Center for Biotechnology, Accessed 2010 at http://www.ncbi.nlm.nih.gov/

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Cartilage

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CARTILAGE
▪ Cartilage is a firm,
nonmineralized connective
tissue that serves as a
skeletal tissue in the body.

Figure 8-8

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 Figure 19-3

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▪ Chondroblasts, lie
internal to the
perichondrium and
produce cartilage matrix.

▪ Chondrocytes, are
mature chondroblasts
that maintain the
cartilage matrix.

Figure 8-8

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▪ Hyaline cartilage is the most
common type found in the
body and contains only
collagen fibers as part of its
matrix.

Figure 8-8

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▪ Cartilage can develop or grow in size in two ways:
▪ interstitial growth and appositional growth.

▪ Interstitial growth is growth from deep within the tissue by the
mitosis of each chondrocyte, producing larger numbers of
daughter cells within a single lacuna, each of which secretes
more matrix, thus expanding the tissue.

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▪ Because it has no vascularity of its own, cartilage takes longer to
repair than does vascularized bone.
▪ Cartilage also has no nerve supply within its tissue.
▪ Thus cartilage, even when subjected to trauma or surgery, does
not produce overly painful symptoms.

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Bone

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BONE
▪ Bone is a rigid connective
tissue that constitutes most of
the mature skeleton.
▪ Thus bone protects and
structurally supports soft
tissue and also serves as an
attachment mechanism.
▪ Bone aids in movement,
manufactures blood cells by
way of its red bone marrow,
and is a storehouse for
calcium and other minerals.

Figure 8-9
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▪ When bone is examined
grossly, the outer part of bone
is covered by periosteum.
▪ Deep to the periosteum is a
dense layer of compact
bone.
▪ Deep to the compact bone is a
spongy bone, or cancellous
bone.

Figure 8-9
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▪ On the innermost part of
bone in the medullary
cavity is the bone
marrow.
▪ This gelatinous
substance is where the
stem cells of the blood
are located and
lymphocytes are
created and B-cells
mature.

Figure 8-9
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▪ Bone consists of cells and a partially mineralized
matrix that is 50% inorganic (or mineralized) material.
▪ It is this inorganic substance in a crystalline formation
of mainly calcium hydroxyapatite with the chemical
formula of Ca10 (PO4)6(OH)2 that gives bone its
hardness.
▪ This inorganic material has matrix packed between its
bone cells.
▪ The matrix is composed of organic collagen fibers and
intercellular substance.

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▪ Bone matrix is initially formed
as osteoid, which later
undergoes mineralization.
▪ The osteoid is produced by
osteoblasts, cuboidal cells
that arise from fibroblasts.
▪ Osteoblasts are also involved
in the later mineralization of
osteoid to form bone.
▪ Always present in the
periosteum is a layer of
osteoblasts at the external
surface of the compact bone to Figure 8-10
allow for the remodeling of
bone and to allow repair of
injured bone.
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▪ Within fully mineralized bone
are osteocytes, which are
entrapped mature
osteoblasts.

Figure 8-10

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▪ The cytoplasmic
processes of the
osteocyte radiate
outward in all directions
in the bone and are
located in tubular canals
of matrix, or canaliculi.
▪ These canals provide for
interaction between the
osteocytes.
Figure 8-10

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▪ Bone matrix in compact bone
is formed into closely apposed
sheets, or lamellae
▪ Contain osteocytes

▪ This highly organized
arrangement of concentric
lamellae form concentric
layers of matrix into cylinders
or osteons.
▪ The Haversian canal (or
osteonic or central canal) is a
central vascular canal within
the each osteon, surrounded
by the lamellae.
Figure 8-11A

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 The osteon is the unit of structure in compact
bone and consists of 5 to 20 lamellae.
This arrangement in the osteon is similar to
the growth rings in a cross section of a tree
trunk.
However, unlike tree rings that form at a rate of
one per year, an entire Haversian system is
produced all at the same time, no matter the
number of concentric lamellae that may be
involved.

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 Nanci A. Ten Cate ’s Oral Histology, ed 7. Mosby, St. Louis, 2008
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▪ Located on the outer part
of the Haversian system
in compact bone are
Volkmann canals, or
similar nutrient canals
that contain the same
vascular and nerve
components as the
Haversian canals, also Figure 8-11A
lined by endosteum.

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▪ Lamellae of the matrix of cancellous bone are not arranged into
concentric layers around a central blood vessel as with the
compact bone, but rather their concentric rings are formed into
cone-shaped spicules.
▪ Osteocytes in lacunae with their cytoplasmic processes are
located between the lamellae of the trabeculae.

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Development of Bone

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▪ Bone development, or ossification, has two methods of
development: intramembranous and endochondral ossification.
▪ The bone produced by these developmental methods is
microscopically the same; only the process of formation is
different.

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▪ Intramembranous
ossification is
formation of osteoid
between two dense
connective tissue
sheets, which then
eventually replaces Figure 8-12
the outer connective
tissue.

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▪ The maxilla and the majority of the mandible are formed by
intramembranous ossification.

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 Figure 8-13

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▪ Appositional
growth, with layered
formation of bone
along its periphery, is
accomplished by the
osteoblasts, which
later become
entrapped as Figure 8-10
osteocytes.

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▪ The cell that causes
resorption of bone is the
osteoclast.
▪ It is a large
multinucleated cell
located on the surface of
secondary bone in a
large, shallow pit created
by this resorption,
Howship lacuna.

Figure 8-15

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 NCI, Accessed 2010, at http://training.seer.cancer.gov/

RBC, Active Platelet, and Leukocyte

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▪ Skeletal muscles are also called striated muscles because the
muscle cells appear striped microscopically.
▪ Each muscle is composed of numerous muscle bundles, or
fascicles, which then are composed of numerous muscle cells or
myofibers.

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 Figure 8-18

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▪ A nerve is a bundle of neural
processes outside the central
nervous system and in the
peripheral nervous system.

Figure 8-19

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▪ The two functional types of nerves are afferent
and efferent nerves.
▪ An afferent nerve, or sensory nerve, carries
information or relays impulses from the
periphery of the body to the brain (or spinal
cord).
▪ An efferent nerve, or motor nerve, carries
information away from the brain to the
periphery of the body.

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▪ The nervous system has two main divisions: the central nervous
system (CNS) and the peripheral nervous system (PNS).
▪ These two parts are not separate but reliant on each other and
thus constantly interacting.
▪ The CNS consists of the brain and spinal cord.
▪ The PNS consists of the spinal and cranial nerves and includes
both the somatic and the autonomic nervous systems.

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