Chapter 4,5,6,9 A&P Lecture PDF

Summary

This document is a set of lecture notes covering various topics in anatomy and physiology, including glands, cell junctions, inflammation, skin repair, aging, perspiration, pigmentation, and thermoregulation.

Full Transcript

Chapter 4 A&P
(glands, cell junctions, inflammation)
Glands
4.1 Four Types of Tissue
(2 of 3)
Epithelial
tissue
–Covers exposed surfaces

–Lines internal passageways

–Forms glands
Epithelial tissue
includes epithelia and glands
–Epithelia
(singular, epithelium)
▪Layers of cells covering internal or external
surfaces
–Glands
▪Structures that produce fluid secretions
4.3 Classification of Epithelia

Cuboidal
epithelia

–Simple
cuboidal
epithelia

▪Secretion and absorption

▪Glands and portions of kidney tubules

–Stratified
cuboidal
epithelia

▪Relatively rare

▪Ducts of sweat glands and mammary glands
Glandular epithelia- a type of tissue that produces and releases
substances in the body

–Glands
are collections of epithelial cells that produce secretions

–Endocrine glands- through the bloodstream
▪Release hormones that enter bloodstream
▪No ducts

–Exocrine glands- on the skin
▪Produce exocrine secretions
▪Discharge secretions through ducts onto epithelial surfaces
Gland structure
–Unicellular glands
–Multicellular glands

Unicellular glands
–Goblet cells are unicellular exocrine glands

–Endocrine glands
▪In epithelia of intestines
▪Secrete mucin, which mixes with water to form mucus
Multicellular exocrine glands are classified by

Examples of multicellular exocrine glands include:

Sweat glands: Also known as sudoriferous glands

Oil glands: Also known as sebaceous glands

Salivary glands: Contain serous cells that secrete a protein-rich fluid, and mucous cells that
secrete mucins

Multicellular glands are tubular

Simple glands: Have a single, continuous duct
Compound glands: Have branched ducts
Tubular glands: Have tubular secretory units with straight or coiled tubes
 Merocrine secretion
–Released by secretory vesicles (exocytosis)
–Example: merocrine sweat glands

Apocrine secretion
–Released by shedding cytoplasm
–Example: mammary glands
Holocrine secretion
–Released by cells bursting, killing gland cells
–Gland cells replaced by stem cells
–Example: sebaceous glands
Types of secretions produced by exocrine glands
–Serous glands
▪Watery secretions
–Mucous glands
▪Secrete mucins
–Mixed exocrine glands
▪Both serous and mucous
Cell Junctions
A characteristic of epithelia is cellularity (cell junction)

cellularity is a characteristic of epithelial tissue, which is made up
of cells that are tightly bound together with little to no space
between them
Intercellular connections
–Cell junctions!
▪Form bonds with other cells or extracellular material
1.Gap junctions- allow rapid communication, held together by
connexons, allow small molecules and ions to pass,
coordinate contractions in heart muscle
2.Tight junctions- between two plasma
membranes,adhesions belt attaches to terminal web, prevent
passage of water and solutes
keep enzymes, wastes, and acids in the lumen of the
digestive tract
3.Desmosomes → next slide!
Intercellular connections CONTINUED

3.Desmosomes- CAMs and proteoglycans link opposing plasma
membranes

Spot desmosomes- tie cells together, allow bending and twisting,

Hemidesmosomes- attach cells to the basement membrane
Inflammation
4.11 Tissue Injuries and Repair
(1 of 4) Learning Outcomes: Describe how injuries
affect the tissues of the body.
Tissues respond to injury in two stages
1.Inflammation
(inflammatory response)
2.Regeneration: to restore normal function
Inflammatory response
–Can be triggered by:
▪Trauma (physical injury)
▪Infection (the presence of pathogens)
–Damaged cells release prostaglandins, proteins, and
potassium ions
–Damaged connective tissue activates mast cells
Process of inflammation
–Lysosomes release enzymes that destroy the injured cells
and attack surrounding tissues
–Tissue destruction is called: necrosis
▪Begins several hours after injury

Necrotic tissues and cellular debris (pus) accumulate in the
wound
–Abscess is pus trapped in an enclosed area
The ability to regenerate varies among tissues
–Epithelia, connective tissues (except cartilage), and smooth
muscle regenerate well
–Skeletal muscle, cardiac muscle, and nervous tissues
regenerate poorly, if at all
–Damaged cardiac muscle cells are replaced by fibrous
tissue through fibrosis
 Chapter 5 A&P
(Skin repair and aging, types of perspiration, pigmentation,
apocrine vs merocrine, thermoregulation)
Skin repair
5.2 The Dermis

Skin damage
–Loss of skin turgor is caused by
▪Dehydration (reversible)
▪Aging
▪Hormones
▪UV radiation
–Excessive distortion of skin from pregnancy or weight gain may
cause stretch marks
Aging
5.10 Aging and the Integumentary System

Learning Outcomes:
Summarize the effects of aging on the skin.

Effects of aging on skin
–Epidermis thins
–Number of dendritic cells decreases
–Vitamin D3 production declines
–Melanocyte and glandular activities decline
–Blood supply to dermis is reduced
–Function of hair follicles declines
–Dermis thins and elastic fiber network shrinks
–Sex-specific hair and body fat distribution fades
–Repair rate slows
Perspiration
5.1 Epidermis
(11 of 12)
Water is lost from skin in two ways
–Insensible perspiration
▪Water diffuses across stratum corneum and evaporates from skin
▪500 mL per day
▪Rate increases if stratum corneum is damaged (ex: from burns)
–Sensible perspiration
▪Water excreted by sweat glands
 Apocrine sweat glands
–Found in armpits, around nipples, and in pubic region
–Secrete products into hair follicles via merocrine secretion
–Produce sticky, cloudy secretions
▪Nutrient source for bacteria, which cause odors
–Surrounded by myoepithelial cells
▪Squeeze secretions out of glands in response to hormonal or
nervous signals
 Eccrine(merocrine) sweat glands
–Coiled, tubular glands that discharge directly onto skin surface
(sensible perspiration)
–Widely distributed on body surface
▪Especially on palms and soles
–Secretions are 99 percent water plus salt, etc.
–Functions include
▪Cooling surface of skin to reduce body temperature
▪Excreting water and electrolytes
▪Providing protection from environmental hazards
–Eccrine sweat glands

▪Controlled precisely; sweating may occur locally
Pigmentation
5.4 Skin Color
(2 of 5)
Melanin
–Red-yellow or brown-black pigment
–Produced by melanocytes
–Stored in intracellular vesicles (melanosomes)
▪Transferred to keratinocytes
▪Dark-skinned people have large, numerous melanosomes
–Protects skin from ultraviolet (UV) radiation
▪Small amounts of UV radiation are beneficial
▪Too much can damage DNA and cause cancer
 Carotene
–Orange-yellow pigment
–Found in orange vegetables
–Accumulates in epidermal cells, deep dermis, and subcutaneous
layer
–Can be converted to vitamin A, required for
▪Maintenance of epithelia
▪Synthesis of photoreceptor pigments in eye
 Blood flow and oxygenation influence skin color
–Hemoglobin is bright red when bound to oxygen
▪When blood vessels dilate from heat, skin reddens
▪When blood flow to skin decreases, skin pales
–Hemoglobin turns dark red when oxygen is released
▪Can result in cyanosis
(bluish skin)
▪May be caused by extreme cold, heart failure, severe asthma, etc.
 Illness and skin color
–Jaundice
▪Buildup of bile produced by liver
▪Skin and whites of eyes may turn yellow

–Pituitary tumor
▪Excess MSH increases production of melanin

–Addison’s disease
▪Causes pituitary gland to release excess ACTH, which has an
effect similar to MSH
–Vitiligo
▪Loss of melanocytes causing loss of color
Apocrine vs Merocrine
Apocrine and merocrine glands are both types of exocrine glands, which secrete products
through ducts. The main differences between the two are how they release their
secretions, their location, and the composition of their secretions:

Release method
Apocrine glands release their secretions by pinching off parts of the cell membrane, while merocrine
glands release their secretions through exocytosis, which doesn't damage the cell.
Location
Apocrine glands are found deep within the skin, while merocrine glands are found on the surface of
the skin.
Secretion composition
Apocrine gland secretions are thicker and contain nutrients for skin bacteria, while merocrine gland
secretions contain water and sodium chloride. SALTY
Thermoregulation
Thermoregulation is the process by which an organism maintains its body temperature
within a certain range, even when the external temperature is different. It's a key part of
homeostasis, which is the state of dynamic stability within an organism's internal
conditions.

Here are some key points about thermoregulation:

How it works
The hypothalamus is the body's thermostat, and it regulates temperature homeostasis by balancing
heat production and heat loss. The hypothalamus contains temperature sensors that receive
information from the body's peripheral and central thermoreceptors. These sensors detect surface
temperatures and core temperatures, respectively.

–Thermoregulation

▪The main function of sensible perspiration

▪Eccrine sweat glands work with cardiovascular system to regulate
body temperature
 Chapter 6 A&P
(bone function, compact vs spongy bone, long bone 4 cell
types: periosteum, endosteum, intramembranous, exercise
effect on bone, hormones, calcium, parathyroid hormone vs
calcitonin)
Bone function
 Primary functions of the skeletal system
–Support
–Storage of minerals and lipids
–Blood cell production
–Protection
–Leverage
Compact vs Spongy bone
 Osteon—cylindrical functional unit of compact bone
Compact bone is denser and stronger than spongy bone
 Spongy bone lacks osteons
Osteons- Osteons serve as the functional unit of bone. Their thick lamellar
rings provide mechanical support and strength to bone

–Red bone marrow
▪Forms blood cells
▪Contains blood vessels that supply nutrients to
osteocytes by diffusion

–Yellow bone marrow
▪Stores fat
Long bone
Mineral storage
Long bones store minerals like calcium, phosphorus, sodium, and magnesium, which are essential for
regulating physiological activities.

Structure and support

Long bones provide strength, structure, and stability to the skeleton.
Periosteum
 Periosteum—membrane that covers outside of bones
–Except within joint cavities
–Outer, fibrous layer and inner, cellular layer
–Fibers are interwoven with those of tendons
–Perforating fibers—fibers that become incorporated into
bone tissue
▪Increase strength of attachments
Endosteum
 Endosteum—incomplete cellular layer that lines medullary
cavity
–Active during bone growth, repair, and remodeling
–Covers trabeculae of spongy bone
–Lines central canals of compact bone
–Consists of flattened layer of osteogenic cells
Intramembranous
Intramembranous ossification is a process that develops bones from sheets of
connective tissue membranes, and is involved in the formation of certain flat
bones of the skull, the clavicles, and some irregular bones
Exercise effect on bone
 Effects of exercise on bone
–Mineral recycling allows bones to adapt to stress

–Heavily stressed bones become thicker and stronger
–Exercise, particularly weight-bearing exercise, stimulates osteoblasts

Bone degeneration
–Bone degenerates quickly

–Up to one-third of bone mass can be lost in a few weeks of
inactivity
Hormones
6.7 Exercise, Nutrition, and Hormones
(4 of 4)
Nutritional and hormonal effects on bone
–Growth hormone and thyroxine stimulate bone growth

–Sex hormones
▪Estrogen and testosterone stimulate osteoblasts

–Parathyroid hormone and calcitonin maintain calcium ion
homeostasis
Parathyroid hormone and calcitonin maintain calcium ion homeostasis

Parathyroid hormone
(PTH)
–Produced by parathyroid glands in neck
–Increases blood calcium ion levels by
▪Stimulating osteoclast activity (indirectly)
▪Increasing intestinal absorption of calcium by enhancing calcitriol
secretion by kidneys
▪Decreasing calcium excretion by kidneys
Calcium
 Characteristics of bone
–Dense matrix due to deposits of calcium salts
–Osteocytes (bone cells) within lacunae organized around
blood vessel
–Canaliculi

▪Narrow passageways that allow for exchange of
nutrients, wastes, and gases
–Periosteum
▪Covers outer surfaces of bones (except at joints)
▪Consists of outer fibrous and inner cellular layers
Bone development
–Ossification (osteogenesis)—bone formation
–Calcification—deposition of calcium salts
▪Occurs during ossification
–Two forms of ossification
▪Endochondral ossification
▪Intramembranous ossification

–Some human bones grow until about age 25
Parathyroid hormone vs calcitonin
Parathyroid hormone (PTH) and calcitonin are hormones that work together to regulate
calcium levels in the blood

Parathyroid hormone (PTH)
Secreted by the parathyroid glands in the neck, PTH increases calcium levels in the blood by
activating osteoclasts, which break down bone to release calcium. PTH also helps the kidneys absorb
calcium

Calcitonin
Produced by the C-cells in the thyroid gland, calcitonin decreases calcium levels in the blood by
inhibiting osteoclasts and increasing the amount of calcium excreted in urine

The levels of both PTH and calcitonin are controlled by blood calcium levels:

PTH: The parathyroid glands release PTH when blood calcium levels are low.
Calcitonin: The thyroid gland releases calcitonin when blood calcium levels are high.
Chap 9
Functional classifications of joint
 Two classification schemes
–Structural (anatomy)
–Functional (range of motion)
Joint structure determines function
 Structural classifications
–Fibrous
–Cartilaginous
–Bony
–Synovial

Functional classifications

–Synarthrosis
(immovable joint)
–Amphiarthrosis
(slightly movable joint)
–Diarthrosis
(freely movable joint)
Synarthrosis (immovable joint)
–Very strong
–Edges of bones may touch or interlock
–May be fibrous or cartilaginous
–Four types of synarthrotic joints
▪Suture
▪Gomphosis
▪Synchondrosis
▪Synostosis
 Synovial joints (diarthroses)
–Freely movable joints
–At ends of long bones
–Surrounded by joint capsule (articular capsule)
▪Contains synovial membrane
–Synovial fluid from synovial membrane
▪Fills joint cavity
–Articular cartilage
covers articulating surfaces
▪Prevents direct contact between bones
Synovial joints
 Synovial joints are mobile but relatively weak
Stabilized by accessory structures
–Cartilages and fat pads
–Ligaments
–Tendons
–Bursae
 Tendons
–Attach to muscles around joint
Bursae
–Small pockets of synovial fluid
–Cushion areas where tendons or ligaments rub
against other tissues
Factors that stabilize synovial joints
–Prevent injury by limiting range of motion
▪Collagen fibers of joint capsule and ligaments
▪Shapes of articulating surfaces and menisci
▪Other bones, muscles, or fat pads
▪Tendons attached to articulating bones
Sprain- ligament with torn fibers
Movements, Triaxial etc
 Movements are described in terms that reflect the
–Plane or direction of movement
–Relationship between structures
Planes of movement
–Monaxial—1 plane (e.g., elbow)
–Biaxial—2 planes (e.g., wrist)
–Triaxial—3 planes (e.g., shoulder)
 Saddle joint
–Articular faces fit together like a rider in a saddle
–Biaxial
Pivot joint
–Rotation only
–Monaxial
Ball-and-socket joint
–Round head in a cup-shaped depression
–Triaxial