Muscle Physiology PDF

Summary

This document provides a detailed overview of muscle physiology, covering the different types of muscles (skeletal, smooth, and cardiac), their structure, properties, and functions. It explains the organization of skeletal muscle, including the epimysium, perimysium, and endomysium, and describes the components of muscle fibers and sarcomeres. The document also touches on the role of myofilaments, organelles like mitochondria and sarcoplasmic reticulum, and the functions of the sarcolemma and T-tubules in muscle contraction.

Full Transcript

MUSCLE PHYSIOLOGY

Part 1 – Skeletal Muscle

Nicole A M Herbert, PhD
[email protected]
Learning Objectives

At the end of the lecture, students should be able to:

Understand the basic components of skeletal muscle, the muscle fiber,
and the myofibril.
Give examples of muscle functions.
Understand the organization of the skeletal muscle.
Describe the types of muscles and muscle fibers.

Describe the physiological events of muscle contraction.
Types of Muscles
Skeletal (40% of the body)
Voluntary muscle; controlled consciously
Striated muscle, multinucleate
Attached to the skeleton
Locomotion, posture, body temperature.

Smooth (10% of the body)
Involuntary muscle; controlled unconsciously
Non-striated muscle, one nucleus per cell
In the walls of blood vessels and internal organs
Respiration, digestion, blood circulation.

Cardiac
Controls itself with help from nervous and
endocrine systems
Striated muscle, one nucleus per cell
Only in the heart
Blood circulation
Muscle Properties

MUSCLES HAVE FOUR SPECIFIC PROPERTIES THAT ENABLE
THEM TO PERFORM THEIR FUNCTIONS EFFECTIVELY.
Contractility - The ability to contract or shorten, allowing muscles to generate
tension.

Extensibility - Is the property of muscles that allows them to be stretched or
lengthened beyond their resting length.

Elasticity - The ability to return to its original shape after being stretched or
contracted.

Excitability - The capacity to receive and respond to stimuli (from the motor neuron,
neurotransmitters, hormone, etc).
Key Points
General Characteristics of a Muscle Fiber

There are three types of muscle: skeletal,
smooth, and cardiac

Muscle contraction is essential for a wide
range of physiological functions including
locomotion, respiration, blood and lymph
circulation

Muscle fibers have four specific properties:
Contractility, Excitability, Extensibility, and
Elasticity
Skeletal Muscle

Primary function is to enable movement of the body
– Attached to the bones of the skeleton viatendons

– Skeletal muscles work in coordination with the skeletal system
to produce voluntary movements, such as walking, running, and
lifting objects.
– Most segments have one or more muscles on both sides either
to increase or decrease its angle.
– Is stimulated by a motor neurone

– Under voluntary (conscious) control
 Skeletal Muscle Structure

EPIMYSIUM – A fascia (thin sheath) of fibrous
Tendon
connective tissue that surrounds the entire
muscle.
Bone FASCICLE - A small bundle or cluster of muscle
fibers
Epymysium
(Surrounds the PERIMYSIUM - Connective tissue extensions
muscle/muscle belly) from the epimysium that surround each fascicle.

ENDOMYSIUM - Connective tissue extensions
from the perimysium that surround the muscle
Perimysium fibers and are attached to the sarcolemma.
(Surrounds the fascicle)
MYOFIBRILS - Each muscle fiber contains
several hundred to several thousands myofibrils.
Each myofibril is composed by a linear series of
repeating sarcomeres
Fascicle
(Bundle of muscle fibers) MYOFILAMENTS - Are responsible for muscle
contraction. Composed of thin and thick
Endomysium filaments.
(Surrounds the Muscle Myofibril
fiber) (Muscle cell)

Myofilaments
(Thin and thick filaments)
 Skeletal Muscle Structure
EPIMYSIUM – A fascia (thin sheath) of fibrous
connective tissue that surrounds the entire
muscle.
Tendon
FASCICLE - A small bundle or cluster of muscle
fibers
Bone

PERIMYSIUM - Connective tissue extensions
Epymysium from the epimysium that surround each fascicle.
(Surrounds the
muscle/muscle belly)

ENDOMYSIUM - Connective tissue extensions
from the perimysium that surround the muscle
Perimysium fibers and are attached to the sarcolemma.
(Surrounds the fascicle)

MYOFIBRILS - Each muscle fiber contains
several hundred to several thousands myofibrils.
Each myofibril is composed by a linear series of
repeating sarcomeres
Fascicle
(Bundle of muscle fibers)
MYOFILAMENTS - Are responsible for muscle
Endomysium contraction. Composed of thin and thick
(Surrounds the Muscle Myofibril
fiber) (Muscle cell)
filaments.

Myofilaments
(Thin and thick filaments)
SARCOLEMMA
– It is a thin cell membrane enclosing a skeletal muscle fiber (cell)
– A special feature of the sarcolemma is that it invaginates into the sarcoplasm of the
muscle cell, forming membranous T-tubules.
– FUNCTION: to carry depolarization from action potentials to interior of fiber
Level of Organization in Skeletal Muscle
MUSCLE FIBERS
Bundle of myofibril – elongated shape
Contain the basic contractile unit (sarcomere)

SARCOMERE
– Contain the myofilaments, basic contractile unit of striated muscle fibers (Found between Z
LINES or Z discs)
– Their arrangement gives the striation pattern.
Myofilaments
Myofilaments are responsible for
muscle contraction

Thin filament
Actin, Troponin complex, Tropomyosin

Thick filament
Myosin (two heads)

Myosin (60%), Actin and Tropomyosin – Muscle Proteins
Arrangement of Filaments in a Sarcomere
Arrangement of Filaments in a Sarcomere
A Myosin Filament (Thick Filament)
Myosin heads

Heavy
Chain
Light
Chain
Weymouth
Actin binding
site

ATP binding
site

Myosin tail Flexible hinge

Are composed of multiple MYOSIN molecules

– Myosin molecule contains a TAIL of intertwined helices and 2 globular HEADS
that can bind both ATP and ACTIN

Functions as an ATPase enzyme – uses ATP as an energy source for
contraction

– Approximately 500 myosin heads of a thick myosin filament form cross-bridges
that interact with actin to shorten the sarcomere
An Actin Filament (Thin Filament)
Troponin C
I
Troponin T

Are composed of ACTIN, TROPOMYOSIN, and TROPONIN COMPLEX
– 2 helical strands of actin protein (contains myosin binding sites)
All intertwined together as a
large helical complex
– 2 helical strands of tropomyosin protein

– Troponin is a complex of three globular protein subunits (C, I and T)
TnC – Calcium-binding subunit (no calcium, no contraction!)

TnI – Inhibitory subunit

TnT – Tropomyosin binding subunit
Organelles of the Muscle Cell (Fiber)

MITOCHONDRIA

– Power plant of a cell (generates ATP)

– Provides myofibrils with large amounts of energy allowing muscle contraction

– Slow-Twitch fibers (Type 1 – Red, aerobic) have more numbers of

mitochondria
slowtwiton
namemore
mitochondriabecause
theyrequiremoreATP
Organelles of the Muscle Cell (Fiber)

SARCOPLASMIC RETICULUM

– Is a specialized endoplasmic reticulum

– Very important for muscle contraction

– Regulates calcium storage, release and
reuptake

– Bigger in fast contracting fibers (white)
Organelles of the Muscle Cell (Fiber)

T-TUBULES

– Tubules arranged transversely to the myofibril

– Periodic invaginations of the sarcolemma in muscle cell

– Allows rapid transfer action potentials to the interior of the fiber.

– Presence of voltage sensitive receptor (dihydropyridine receptor in tubule)
attached physically to the ryanodine receptor voltage gated in the sarcoplasmic
reticulum.
Key Points
The Muscle Fiber
The skeletal muscle is surrounded by several
layers of connective tissue (epimysium,
perimysium, and endomysium) that provide
strength and stability to the muscle and prevent
it from ripping while contracting.
A muscle fiber is enclosed by a plasma
membrane called the sarcolemma.
The sarcoplasmic reticulum (SR) is a specialized
organelle responsible for storing, releasing, and
reuptake of calcium ion.
T-tubules allow for rapid transmission of the
action potential into the cell and play an
important role in regulating cellular calcium
concentration.
Muscle cells are multinucleate
Key Points
The Myofibril

Myofibrils are made up of sarcomeres, the
smallest functional units of a muscle.

A sarcomere is composed of filaments of two
proteins, myosin and actin, which are
responsible for muscle contraction.

Myosin is a thick filament with a globular head
at one end.

An actin filament is composed of actin,
tropomyosin, and troponin. It is attached to a Z
disk.
Elements of muscle contraction – Action
Potential

Rapid change in voltage across a
membrane.
Based on ratio of ions – intra and
extracellular
Caused by inflow of Na+ (high extracellular
conc) and outflow of K+ (high intracellular
conc), causing change in voltage and
increase in action potential
Muscle Contraction (Sliding Filaments Model)

neuron

Jafina

offilament doesn'tchange
length

in itiIne
The Sliding Filament Model

Proposed in the early 1950s.
Two British biologists, Hugh Huxley and
Andrew Huxley.
The theory proposes that a muscle
shortens or lengthens because thick and
thin filaments slide over each other
without changing length.

Professor Hugh E. Huxley
(Feb 25th 1924 – July 25th 2013)
SLIDING FILAMENT MODEL OF MUSCLE
CONTRACTION
Before muscle contraction begins Myosin heads bind with
ATP (low energy configuration)

The ATPase activity immediatly cleaves the ATP in ADP and Pi

Cleavage products are kept bound to the head

Head becomes energized in a “cocked position”

Ca2+

Troponin C
Troponin T
SLIDING FILAMENT MODEL OF MUSCLE
CONTRACTION
When calcium ions bind the troponin-tropomyosin complex, active sites
of the actin filaments are uncovered

Myosin heads bind to these sites

The cross bridge is formed

The phosphate ion and ADP are released
SLIDING FILAMENT MODEL OF MUSCLE
CONTRACTION
The cross bridge causes a conformational change in the
head
Myosin heads bend toward the center of the sarcomere, causing the actin to
slide toward the M line – POWER STROKE

The energy that activates comes from the stored ADP
Another ATP molecule will take place causing detachment of the myosin head
from the actin filament to begin a new cycle
Key Points
Muscle Fiber Action
Muscle action is initiated by a nerve
impulse.
If the cell receives the right stimulus, an
action potential occurs which releases
stored Ca2+ ions.
Ca2+ ions bind with troponin, which lifts the
tropomyosin molecules off the active sites
on the actin filament. These open sites
allow the myosin heads to bind to them.
Energy for muscle action is provided when
the myosin head binds to ATP. ATPase on
the myosin head splits the ATP into a
usable energy source.
Key Points
Muscle Fiber Action
Once myosin binds with actin, the myosin
head tilts and pulls the actin filament so
they slide across each other.
Muscle action ends when calcium is
pumped out of the sarcoplasm to the
sarcoplasmic reticulum for storage.
Muscle Physiology Videos

Structure of Skeletal Muscle | Skeletal Muscle Bands | Muscle Tissue | Nerve Muscle
Physiology -YouTube

Muscle Contraction Part 3 The Cross Bridge Cycle - YouTube
 Types of Muscle Fibers
– Skeletal muscles contain both Type I and Type II fibers.
Type I (Red) slowtwitch

– Type I fibers have high aerobic endurance and are suited to low-intensity
endurance activities. Uses more oxygen – myoglobin protein

Type II (White) fasttwitch
– Type II fibers are better for anaerobic or explosive activities.

» Type IIa

» Type IIb

4923124
not
TYPE I MUSCLE FIBERS

Type I - Oxidative Fiber
High aerobic capacity and fatigue
resistance cannotgettiredduetohigh ofATP
Rich in mitochondria (high ATP)
Slow contractile speed (110 ms) = Slow
Twitch
Plentiful in muscles where the main
function is slow prolonged activity (back
muscles)
10–180 fibers per motor neuron
Type IIa Muscle Fibers
Type IIa – Are mixed oxidative-glycolytic fiber
Moderate aerobic (oxidative) capacity and fatigue resistance
High anaerobic (glycolytic) capacity
Fast contractile speed (50 ms) = Fast Twitch
Highly developed sarcoplasmic reticulum
300–800 fibers per motor neuron
Type IIb Muscle Fibers

FTb (Type IIb) – Glycolytic Fiber
Low aerobic (oxidative) capacity and fatigue
resistance

High anaerobic (glycolytic) capacity and motor
unit strength

Fast contractile speed (50 ms)

Highly developed sarcoplasmic reticulum
(rapid Ca2+ release)

300–800 fibers per motor neuron
Functional Classification of Muscles

Agonists — muscle responsible for the movement

Antagonists — oppose the agonists to prevent overstretching of them

Synergists — assist the agonists and sometimes fine-tune the direction of
movement
Muscle Action During Elbow Flexion
Satellite Cell Function

Satellite cells are a type of stem cell located in skeletal muscles.
Are involved in muscle growth and repair.
Are normally in a dormant state but become activated when a muscle is injured
and multiply to form new muscle fibers or myofibers.
Mechano Growth Factor (MGF) in mechanically overloaded muscles
Inflammatory cytokines (Interleukin 6 (IL-6) and Tumor Necrosis Factor alpha
(TNF- ).
Myostatin Function
muscle
remise

Its primary function is to regulate muscle growth and development by
inhibiting the proliferation and differentiation of muscle cells.

Produced and secreted by skeletal muscle cells.

Myostatin has been the subject of intense research in the field of muscle
biology and has been identified as a potential therapeutic target for
conditions associated with muscle wasting, such as muscular dystrophy
and sarcopenia.
 MUSCLE PHYSIOLOGY

Part 2 – Smooth and Cardiac Muscle

Dr. Nicole A M Herbert
[email protected]
Learning Objectives

At the end of the lecture, students should be able to:

– Describe the 2 types of smooth muscle.

– Understand the physical structure of smooth and cardiac
muscle.

– Describe the function of the intercalated disks in the
cardiac muscle.
Smooth Muscle

SMOOTH MUSCLE OF EACH ORGAN IS DISTINCTIVE:

Different physical dimensions to adjust to the organs they are in;

Organization into bundles or sheets to enable coordinated contractions for
functions like digestion and blood flow regulation.

Response to different stimuli, including neural, hormonal and local factors
(O2, CO2, H2).

Receives nerve signals from the autonomic nervous system (Sympathetic
(fight and flight) and Parasympathetic nervous (relaxation) system).

Smooth muscle has various functions depending on the organ it is in,
including peristaltic contraction, regulation of blood flow, and control of airway
diameter
Types of Smooth Muscle

Can be generally divided into
– Single-unit (visceral) smooth muscle

– Multi-unit smooth muscle

e.g. Walls of stomach e.g. Lungs and ciliary
and bladder muscle of eye
 Types of Smooth Muscle

SINGLE-UNIT SMOOTH MUSCLE
– Also called visceral, syncytial or unitary smooth
muscle
– Fibers are arranged in sheets or bundles
Cell membranes are connected to each
other
The force generated in one muscle fiber can
be transmitted to the next (myogenic)
Contract together as a single unit
 Types of Smooth Muscle

SINGLE-UNIT SMOOTH MUSCLE

– Cell membranes are joined by many gap junctions
Ions can flow freely from one muscle cell to the next
Fibers contract together
– Locations
Gastrointestinal tract, bile ducts, ureters, uterus, and many blood vessels
 Types of Smooth Muscle

MULTI-UNIT SMOOTH MUSCLE
– Discrete, separate smooth muscle fibers
– Each muscle fiber contracts independently
– Innervated by a single nerve ending (neurogenic)
– Locations
Ciliary muscles of the eyes
Iris muscle of the eyes
Base of hair follicles
Smaller airways to lungs
Walls of large blood vessels
 Particularities of Smooth Muscle Iissiised

S.Ties

Fusiform/spindle shape
otzdiskf.name

Smooth muscle has only one nucleous at the cell’s center.

No striations

Smooth muscle does not contain myofibrils or sarcomere,
but it contains thick and thin filaments, and contract via a
sliding filament mechanism.
 Particularities of Smooth Muscle

Smooth muscle does not have the same striated
arrangement of actin and myosin filaments

The actin filaments are attached to dense bodies, which are
analogous to the Z-discs in striated muscle sarcomeres.

Some bodies are attached to cell membrane
Some bodies are dispersed inside the cell

Myosin filaments are inserted among the actin filaments. No
troponin

Contraction different and is more intense than in skeletal
muscle
 Particularities of Smooth Muscle
Myosin filaments have side-polar cross-bridges

– They are arranged so that the bridges on one side bend in one
direction and those on the other side bend in the opposite direction

– This configuration allows the myosin to pull an actin filament
simultaneously in opposite directions

no
int
peas
am
Particularities of Smooth Muscle
Myosin filaments have side-polar cross-bridges

– Smooth muscle can contract as much as 80% of their length
Skeletal muscle only 30% n
rg
Particularities of Smooth Muscle

Low frequency of cross-bridge cycles
– Low energy to maintain the contraction - 1/10 to 1/300 of
the energy necessary to contract skeletal muscle
(fatigue resistant – low ATP)
– Once smooth muscle initiates the contraction, a low
energy is needed to keep the tonic contraction for hours.
– Some smooth muscle has a tonic contracting (resting
tone), that can last for hours or days. E.g. arteries
 Particularities of Smooth Muscle
Sarcoplasmic reticulum is not well developed
– It is not the major source of Ca2+ for smooth muscle
contraction – extra cellular fluid is!
Not present in all smooth muscle fibers

– Lies near the cell membrane in some larger smooth muscle
cells

– Small invaginations of the cell membrane, called
CAVEOLAE, that make contact with the surface of SR.
Rudimentary T-Tubule.
Is believed to excite calcium release from the SR.

– The more extensive the SR in the smooth muscle fiber, the
more rapidly it contracts (Ca2+)
 Smooth Muscle Contraction

Smooth muscle uses calmodulin as a calcium-binding protein to
regulate the contraction process iinstead of troponin.

1. Calcium-bound calmodulin, resulting in its activation.
2. Activated calmodulin then activates an enzyme
called myosin light chain kinase (MLCK). MLCK
phosphorylates a specific region of myosin. dependenton
3. Phosphorylated myosin binds to actin, forming a
cross-bridge between myosin and actin allowing the
muscle cell to contract.
4. When the ion calcium concentration is reduced,
myosin phosphatase removes the phosphate from
the myosin light chain, causing muscle relaxation
actslikeadisk

stractualintegrity
Key Points
General Characteristics of Smooth
Muscle
Smooth muscle can be divided into two types: 1) Multi-
unit smooth muscle; 2) Single-unit smooth muscle.

Dense bodies are small, dense structures found within
the cytoplasm of smooth muscle cells. They serve as
anchoring points for actin filaments. These dense bodies
are functionally analogous to the Z-discs found in
skeletal muscle.

The arrangement of actin, myosin, and dense bodies in
smooth muscle allows for the coordinated contraction and
relaxation of the muscle.
Key Points
General Characteristics of Smooth
Muscle
Smooth muscle contracts involuntarily without conscious
control. It is found in the walls of various organs and
structures throughout the body, such as blood vessels,
the digestive system, respiratory system, and
reproductive system.

Smooth muscle performs essential functions, such as
regulating blood pressure, propelling food through the
digestive tract, and facilitating the movement of air in the
lungs.

Compared to skeletal muscle, smooth muscle exhibits
slower contraction and relaxation times. The slower
kinetics of smooth muscle contraction and relaxation are
important for sustained contractions, such as maintaining
muscle tone in blood vessels or in the uterus.
Cardiac Muscle

Cardiac muscle cells are called cardiomyocytes or cardiocytes.

These cells make up the myocardium, the muscle layer of the heart.

The myocardium contracts to pump blood throughout the body, supplying
organs and tissue with oxygen and nutrients.
 Cardiac Muscle
The structure of cardiac muscle share some similarities with
skeletal muscle
– Fibers are striated
– Myofibrils are made up from actin and myosin filaments
Similar organization of the sarcomere

– Contains a less developed Sarcoplasmic Reticulum
– T-tubules (also release Calcium ions)
 Cardiac Muscle
But cardiac muscle also differs from skeletal muscle in
several ways
– Contraction is involuntary (controlled via autonomic nervous system)
– Fibers are shorter and branched
– Usually uninucleated
– Interconnected by intercalated disks
– Generates their own action potential (pacemaker fibers)
Cardiac Muscle

THE CARDIAC ACTION POTENTIAL IS NOT
INITIATED BY NERVOUS ACTIVITY.

– It is generated by a group of specialized cells
known as pacemaker cells.

– These cells have automatic action potential
generation capability.

– Are found in the sinoatrial node in the right
atrium.

– They produce roughly 60–100 action potentials
every minute.
 Cardiac Muscle
Function
is L
Cardiac muscle is a FUNCTIONAL SYNCYTIUM
– Greek: Syn = together + Kytos = cell
– Do not fuse into a single multinucleated fiber during
embryonic development like skeletal muscle does
(morphological syncytium)
– Cardiac myocytes branch or bifurcate during
development and bind to other myocytes
– Fibers remain separated as distinct cells with their
respective sarcolemma
Electrically connected to each other through
intercalated disks
 Cardiac Muscle
The INTERCALATED DISK is a dark, dense cross-band found in the end
of each myocardial cell

– Continuous with the sarcolemma (wave-like contraction)
– Contain important cell-cell junctions
GAP JUNCTIONS
– Allow rapid diffusion of ions (passive)
– Action potential travel easily
– =electrical coupling (passive movement)

DESMOSOME
– Provide mechanical strength and stability
» Adhesive intercellular junctions
» Tissue integrity
pdisc
Key Points
General Characteristics of a Cardiac
Muscle
Cardiac muscle is a specialized type of muscle found in
the heart. It consists of elongated cells called
cardiomyocytes, which are striated due to the organized
arrangement of actin and myosin filaments.

Cardiac muscle contracts involuntarily, but the contraction
is controlled via ANS.

Intercalated discs are unique structures found between
adjacent cardiac muscle cells. They contain specialized
cell-to-cell junctions called desmosomes and gap
junctions.
Key Points
General Characteristics of a Cardiac
Muscle

Desmosomes provide mechanical strength and stability,
allowing for the transmission of force during contraction.

Gap junctions permit the passage of ions between cells,
enabling electrical coupling.
Structural & Functional Biology
Skin & Integumentary System
Sarah Hooper, DVM, MS, PhD
E-mail: [email protected]
1
 If you can't fly, then RUN.
If you can't run, then WALK.
If you can't walk, then CRAWL.
But whatever you do,
YOU HAVE TO KEEP MOVING.

Martin Luther King, Jr. – Civil Rights Activist and Pastor
2
Learning Objectives:
List the functions of the skin in mammals
Explain the mechanisms that help the skin protect the animal
Explain the components of the skin
Cells layers of the epidermis and relevant cells types
Keratin synthesis
Function and synthesis of melanin
Nerve endings in the skin
Hairs and feathers
Thermoregulation through the skin
Glands of the skin
The hoof 3
 The Skin and the Integumentary System
Skin:
Largest sensory organ in the body
Covers the body thereby protecting cells and tissues
Very important for communication in animals
Piloerection in localized parts of the skin functions as visual signals

From: Sjaastad, Sand, Hove „Physiology of Domestic Animals“
4
 The Skin and the Integumentary System

The skin helps animals recognize the structure of
surfaces, their composition and temperature.

In humans, the skin is an essential component of
our affective behavior.

5
Functions of Skin
Protect against loss of water, electrolytes,
Protection of the body against mechanical and
and other constituents
chemical injury by 3 mechanisms oftheskin
Physical structure of skin Turnover (shedding) of superficial cells
Hair and keratinized surface and hair helps regulate number of
microorganisms and debris on skin
Secretory products surface
Antibacterial and antifungal properties
Normal bacterial flora (aka skin
microbiome)
Prevents invasion by pathogenic bacteria by
occupying microbial niches and producing
compounds that inhibit the growth of other
microorganisms

6
Functions of Skin
Protection of the body against mechanical and
chemical injury
Limitation of loss of water from the body
Immunologic barrier
Thermoregulation
Sensory information provision (pressure,
temperature, pain)
Transmission of emotional and chemical signals
Fat storage
Synthesis of 7-dehydrocholesterol, which is
converted to vitamin D3 by ultraviolet light

7
 Our two case studies – Ollie and Azzy

8
From: https://www.animaldermatologyclinic.com.au/case-studies
 Skin structure:

Use the weblink on the previous slide and the figure
on the right to help you fill in the blanks:

Three main components of the skin:

The __________,
epidermis the outermost layer of skin,
a multilayered epithelium

The ________,
dermis an underlying layer of
vascularized connective tissue

subcutis or hypodermis also known as the
The __________________,
subcutaneous layer.
-------------------------------------------------------------------
Accessory structures, such as hair,
9
feathers, and glands From: Sjaastad, Sand, Hove „Physiology of Domestic Animals“
 The Skin and the Integumentary System
The epidermis

The epidermis is made up of four cell layers:

Stratum corneum (layers of keratinized, dead cells still connected by desmosomes)
____________

Stratum granulosum (flattening of cells, high keratin content)
________________

Stratum spinosum (cells joined by
_______________
Desmosomes providing mechanical strength)
Desmosomes = prominent cell-to-cell junctions
____________
Stratum basale (stem cells)

https://ohiostate.pressbooks.pub/vethisto/chapter/7-structure-of-the-epidermis/

10
 The Skin and the Integumentary System
Haired skin (“thin skin”). Thorax, dog Hairless skin (“thick skin”). Pawpad, dog

Stratum
corneum

Stratum corneum

12
From: Zachary. „Pathologic Basis of Veterinary Disease“
 The Skin and the
Integumentary System
The four cells of the epidermis are……. (Hint:
https://www.ncbi.nlm.nih.gov/books/NBK470464/)

Keratinocytes (the most predominant ones)
Melanocytes
Langerhans’ cells
Merkel’s cells

1) Keratinocytes:
Produce keratin, the major structural protein in the
epidermis
Contribute to the formation of the epidermal water
barrier
Makes up majority of the structure of the skin, hair,
and nails 14
 The Skin and the Integumentary System

Keratin synthesis and the formation of the epidermal water
barrier
I
Cell division occurs in the stratum basale (basal layer).
These cells synthesize tonofilaments (intermediate
keratin filaments).
Cells are pushed into the stratum spinosum
As it enters tonofilaments synthesis continues and the
cell begins to produce:
keratohyalin granules that contain proteins (aid
in aggregation of keratin filaments), helps
convert granular cells to cornified cells
(keratinization) and glycolipids-containing
lamellar bodies

15
Physiologic Variants https://www.ncbi.nlm.nih.gov/books/NBK470464/) From: Ross & Pawlina „Histology: A Text and Atlas“
 The Skin and the Integumentary System

Keratin synthesis and the formation of the epidermal water
barrier

Cells are pushed into the stratum granulosum and continue to
stratum corneum.

Lamellar bodies are discharged by exocytosis into the spaces
between stratum granulosum and stratum corneum

Lamellar bodies + lipid envelope -> epidermal water barrier

The epidermal water barrier prevents entry of fluids and
microorganisms as well as fluid loss from the body

16
From: Ross & Pawlina „Histology: A Text and Atlas“
 The Skin and the Integumentary System
2) Melanocytes:

Melanocyte precursor cells originate in the neural crest
Melanocytes are in close association with a number of
keratinocytes in the epidermis

Normally located in stratum basale are easily recognized by
the presence of melanin granules inside “dendritic”
processes

From: Sjaastad, Sand, Hove „Physiology of Domestic Animals“ 17
 The Skin and the Integumentary System
Melanin protects the skin against nonionizing UV
2) Melanocytes:
irradiation
Synthesis starts in premelanosomes from the
amino acid tyrosine
As more melanin is produced, melanosomes
become more visible at the tip of the dendritic
process being then transferred to neighboring
keratinocytes (pigment donation)

Ando, H., Niki, Y., Ito, M., Akiyama, K., Matsui, M. S.,
Yarosh, D. B., & Ichihashi, M. (2012). Melanosomes are
transferred from melanocytes to keratinocytes through
the processes of packaging, release, uptake, and
dispersion. Journal of Investigative Dermatology, 132(4),
1222-1229.
From: Ross & Pawlina „Histology: A Text and Atlas“
18
 The Skin and the Integumentary System
Melanocytes:

Light skin vs dark skin melanin degradation
Lysosomal activity degradation of melanin is faster in individuals with light skin than
in individuals with dark skin and melanosomes are distributed only in stratum basale)

Two forms of melanin pigments (genetically
determined):
Eumelanin -> brownish black
Pheomelanin -> reddish yellow

Exposure to UV light accelerates the rate
of melanin production as a way to protect From: Sjaastad, Sand, Hove „Physiology of Domestic Animals“

the skin
19
 The Skin and the Integumentary System
3) Langerhans’ cell: dendetriccell 4) Merkel’s cells: torean

Can be seen in the stratum spinosum Modified epidermal cells found in stratum
First line defenders, play a role in antigen basale
presentation Most abundant in skin where sensor perception
Aka dendritic cells are antigen-presenting is acute, such as fingertips
cells
Merkel’s cells are associated with a terminal
disk of an afferent myelinated nerve fiber
(Merkel’s corpuscle -> mechanoreceptor)

From: Ross & Pawlina „Histology: A Text and Atlas“ 20
Case Study it
Navigate to:
https://www.animaldermatologyclinic.com.au/case-
studies/ollie/atopic

What test/procedures were done?
i.iamisnsea

it i i
If the last procedure listed was performed incorrectly
through all skin layers, list these 3 main layers in order of
most superficial to deepest.
epidermis superior

Epidermis
deep
If a superficial skin scrape was performed, what are the
4 cell layers of the epidermis that could be affected?

im feridermis

FYI information on skin scrapes:
https://todaysveterinarypractice.com/dermatology/der
matology-diagnostics-skin-scrapes-hair-plucks/
21
Case Study
Navigate to:
https://www.animaldermatologyclinic.com.au/case-
studies/ollie/atopic

What are the 4 main cells in the epidermis?
keratinocytes
Melanocytes

Langerhanscells
Marketscells

What is something you should be aware of when giving
the treatment when thinking about the 3 mechanisms
that help protect Ollie?
Shiina
L.isuagtf.Ised 3mechanisms
skinstructure
physical

22
 The Skin and the Integumentary System
The dermis

Strong and flexible connective tissue composed by cells
and collagen fibers

Cells of the dermis:
____________
Fibroblasts (primary cells)
Macrophages
Leukocytes
Mast cells

Tissue derived from the epidermis extend into the dermis
and gives rise to sweat glands,
sebaceous glands, and the papillae that form hair and
feathers

https://www.ncbi.nlm.nih.gov/books/NBK535346/ Contributed by Wikimedia Commons, USGOV (Public Domain)

23
The Skin and the Integumentary System

24
 The Skin and the Integumentary System
Other nerve endings in the skin
Hairless skin Haired skin

Dermis

Meissner Merkel Pacini Hair folicle sensor Ruffini
Hypodermis

From: Schmidt, Lang, Heckmann „Physiology of Humans“

In hairless skin only; Only in haired skin;
touchreceptors mechanoreceptors
(tactile hairs)
Deep pressure Respond to Tactile hairs in the
receptors for mechanical whiskers of a cat
mechanical and displacement of
vibratory pressure adjacent collagen
fibers
From: Sjaastad, Sand, Hove „Physiology of Domestic Animals“
25
 The Skin and the Integumentary System
Hairs

Hair follicles are formed by invaginations of
the epidermis into the dermis

After a skin injury, cells in stratum basale are
capable of forming new hair follicles

At the deep end, each follicle is expanded
into a hair root or hair bulb that surrounds a
portion of dermis, the hair papilla From: Sjaastad, Sand, Hove „Physiology
of Domestic Animals“

The matrix region of the hair bulb produces
new daughter cells that are pushed towards
the surface

26
https://www.proteinatlas.org/learn/dictionary/normal/skin
 The Skin and the Integumentary System

The hair shaft consists of keratinized epithelial cells that
are pushed from the hair root outwards the root canal

Cuticle: single layer of dead, scale-like keratinocytes
Cortex: several layers of dead keratinocytes
containing hard keratin
Medulla: dead loosely keratinized cells

Piloerector muscle (aka arrector pili m.): a smooth
muscle associated to hair bulb and anchored to the
outer layer of the dermis (sympathetic innervated)

Hair follicules have cycles of activity
________(growth) ________(regression)
catagen
_________(resting)
telogen
__________(shedding)
antigen exogen
From: Ross & Pawlina „Histology: A Text and Atlas“ 27
 The Skin and the Integumentary System
Feather Types
Flight feathers
Cover feathers (down feathers)

The vane is the flat part of the feather
It consists of barbs that are at angles of about
45 °

The hooklets, which are present only on the
barbules on one side of the barb, hook onto the From: Sjaastad, Sand, Hove „Physiology of Domestic Animals“

smooth barbule from the adjacent barb
The barbules of down feathers lack hooklets

The barbules of down feathers lack hooklets

Feathers from the same feather follicle can have
different pigmentation RUSVM student:
Joe Richichi 28
 The Skin and the Integumentary System
Thermoregulation

Heat transport to the skin. Heat passes through layers
with good insulation properties, the subcutaneous
adipose tissue and fur or plumage.

Mechanisms of heat exchange ->
From: Sjaastad, Sand, Hove „Physiology of Domestic Animals“
29
 The Skin and the Integumentary System

Glands of the skin

Sebaceous glands
Sweat glands
Mammary glands

Virtual histology slides of skin and glands: From: Sjaastad, Sand, Hove „Physiology of Domestic Animals“

http://medcell.med.yale.edu/histology/skin_lab.php#vm-slides 30
 The Skin and the Integumentary System
Sebaceous glands

Duct opens into
A hair follicle (most common)
Pore on the skin surface

Composition: detached, degraded epithelial cells
as well as lipids and proteins

Functions: lubrication of the skin, provides water
impermeability, and inhibition of bacterial growth

Stimulated by testosterone m and

There are no sebaceous glands associated
with feathers. Uropygial glands in waterfowl
produces a secretion that impregnate the From: Sjaastad, Sand, Hove „Physiology of Domestic Animals“
feathers of the bird 31
 The Skin and the Integumentary System

Sweat glands

Eccrine glands:
o Very common in primates
o Open in pores at the skin surface
o Ionic composition is similar to the plasma. In
the duct, Na+ and Cl- are reabsorbed
o Degree of reabsorption depends on the
secretion rate

Apocrine glands:
o Very common in domestic animals
o Open into hair follicle
o Odoriferous secretion composed of fatty
shiny
acids and proteins
From: Sjaastad, Sand, Hove „Physiology of Domestic Animals“
32
 The Skin and the Integumentary System
Mammary gland
Glands + teats = The udder

From: Sjaastad, Sand, Hove „Physiology of Domestic Animals“

Nutrients and water required for milk production
Alveoli (acini): milk-producing units diffuse from blood capillaries and enter into the
Lobuli: clusters of alveoli epithelial cells
Lobi: clusters of lobuli Myoepithelial cells are involved in milk ejection 33
 The Skin and the Integumentary System

Cornified epidermal structures

Hooves, claws, and horns in mammals
Claws in reptiles and birds
Beaks in turtles and birds I t
Shells and scales in reptiles
Scales in fish

Hooves
Horny hoof wall is formed by keratinization of the
cells in the coronary band. Recently produced horn
is pushed downward as new horn is being formed

At the coronary band the dermis of the skin is
continuous with the dermis of the hoof.
From: Sjaastad, Sand, Hove „Physiology of Domestic Animals“
34
Clinical Case Study
Navigate to:
https://www.animaldermatologyclinic.com.au/c
ase-studies/azzy-equine

In equine eosinophilic granuloma, eosinophils and
macrophages are the primarily inflammatory cells. They
are found in what skin layer and cell layer if they
stimulate the maturation of Langerhans cells and
dendritic cells?
skinlayer epidermis

celllayer stratnusspinosum

What is a concern if corticosteroids are used when
thinking about the hoof? (Hint look up condition in
Merck Vet Manual)
distalphalanxsinkslaminess

35
Clinical Case Study
Gross and histological images available at:
https://www.vet.upenn.edu/research/academic
-departments/clinical-studies-new-bolton-
center/centers-laboratories/laminitis-lab-photo-
gallery

36
Thank you
37
 Vet Prep
Structural and
Functional Biology
Meninges Dr. Melissa Kehl

Courtesy of Dr. Melania Crisan
 Learning Objectives

Describe where the spinal cord ends in dog.

Describe membranes around CNS (central nervous system),
spaces they create and the contents of these spaces.

Describe production of CSF, its function and its circulation.

Describe access points to the epidural and subarachnoid spaces,
why these places are preferred, and structures to avoid.
 OVERVIEW central nervous system
(1) brain (2) spinal cord
spinderves
oranges

peripheral nervous system
(3) peripheral nerves

The peripheral nervous system is divided into
(4) sensory or afferent system to cns
(5) motor or efferent system awaycus

SAME

The brain and spinal cord are contained within a continuous space
provided by the cranial cavity of the skull and the vertebral canal.
 epaxiahus.ie

1. spinal cord inside canal
vertebral

ÉÉ 2. dorsal root within vertebrates

4. ventral root
5. spinal nerve
Rib
6. dorsal branch of spinal n.
7. ventral branch of spinal n.
S 8. body of vertebra out p

10. epaxial muscles

thora ran
Transection of the
vertebral column
TVA 5TH Ed. Dyce, Sack and Wensing
 Spinal cord and cauda equina Dog
Spinal cord ends atlas
around
axis
lumbosacral
junction.
The spinal nerves after L7
travel caudally within the
vertebral canal.

They exit when they
00
reach their
corresponding vertebrae.

This cluster of spinal nerves
is known as cauda equina
because it looks like a horse
tail.
FYI

Cauda equina syndrome (CES) is caused by compression of the nerve roots passing from the lower back toward the tail at the level of the lumbosacral
junction. Lumbosacral stenosis is most commonly caused by degenerative changes to the intervertebral disc, arthritis of the joints, and abnormal
proliferation of the ligaments. Dogs with abnormal shape to their last lumbar or sacral vertebrae and German Shepherd dogs are predisposed to
developing lumbosacral stenosis. Neoplasia (cancer) and infection at the level of the lumbosacral disc (discospondylitis) may also cause signs of CES.
What are the symptoms of cauda equina syndrome?
The most common neurologic sign associated with cauda equina syndrome is pain in the lower back. Signs of pain may include decreased willingness to
jump up and climb up stairs, low tail carriage or reduced tail wagging, difficulty posturing to defecate, and whimpering/crying if the lower back is
touched. In some cases, dogs will have a weakness or lameness in one or both hind limbs—this occurs secondary to compression of the nerve root that
supplies the sciatic nerve as it exits at the lumbosacral joint. Severe compression of the nerve roots can lead to fecal and urinary incontinence, which is
irreversible in most cases.
How is it diagnosed?
The first step in diagnosing cauda equina syndrome is through a neurologic examination. The doctor will observe the dog’s gait for any lameness
and/or stiffness. A physical examination will include palpation over the spine to determine the site where the dog is most painful. Manipulation of the
hips and tail will elicit pain response in most dogs suffering this syndrome. The doctor will also test reflexes, proprioception (foot placement), and anal
tone. Radiographs are taken for abnormal shape of the lumbosacral joint, spinal arthritis at the lumbosacral joint, infection of the disc space, or
tumors.
How is it treated?
Dogs that are exhibiting mild pain and have never had an episode of back pain before are usually treated with strict rest and pain medications. In cases
where the dog is not responding to conservative medical therapy or exhibiting neurologic symptoms, surgical intervention is necessary. The procedure
is called a dorsal laminectomy and involves removing the “roof” of the spinal canal to release the entrapped nerve roots and remove the associated
ruptured intervertebral disc, if present.
What is the post-operative prognosis?
Prognosis is very good in dogs with mild neurologic signs (i.e. pain only, mild weakness). Dogs with severe nerve root compression and subsequent
urinary or fecal incontinence have a very poor prognosis, and the majority of dogs never become continent again—even with surgery. Many dogs with
lumbosacral disease have other back problems (i.e. chronic intervertebral disc disease) and hip or other orthopedic disease, which can affect their
recovery after surgery. Recovery is also slower in overweight dogs, and obese patients must be put on a strict diet to reduce their weight.
 Meninges
1
The brain and spinal cord are surrounded by 3 continuous membranes of connective tissue called meninges.

1. DURA MATER
Dura mater – is the outer and thickest layer.
In the vertebral canal, the dura is separated from the periosteum of the bony canal.
Inside the cranial cavity, the dura and the periosteum are fused.

2. ARACHNOID
trabeculae
The arachnoid is attached to the dura and sends delicate trabeculae to the pia.
These trabeculae have blood vessels that course on the surface of the pia.

3. PIA MATER
Innermost meningeal layer.
Intimately follows the brain’s gyri and sulci (bumps and grooves).
Pia is the region of some CSF production. Note:
A 4th membrane which is not a meninx is the
periosteum lining the vertebral canal and skull.
 Meninges
SPINAL CORD
SKULL
spider

Epidural space

jÉÑ

bÉuÉboneandduramater
vertebra havespace

whilebrainskilldoesn'thavethatspace
https://www.marvistavet.com/meningioma.pml
 Vertebral Canal

Dorsal view of the opened
vertebral canal.
The dura mater has been
dissected and is reflected.

Spinal Cord Dura Dorsal Root of a Spinal Nerve
(covered by Mater
pia mater)
TVA 5TH Ed. Dyce, Sack and Wensing.
 Membrane spaces in Vertebral Canal
Epidural space
Only present Spinous
around spinal cord Red line = periosteuminside
areplaced
wheredrugs Process
Blue line = dura mater
Yellowline
Yellow line= =arachnoid
arachnoid
Subdural space Green line = pia mater
(potential space only) arch
Not normally
present
tryS
Subarachnoid
Space
Contains CNS
wheretotakesampleout

Vertebral Body
 Membrane spaces in Cranium
In skull, dura mater is fused to periosteum - hence no epidural space in skull
Red line = periosteum
Blue line = dura mater
Yellow
Yellow line
line = arachnoid
= arachnoid
Green line = pia mater
Olfactory nerve
(surrounded by meninges)
Clinical: Possible route for
meningitis! Nose to brain II cerebar

connection.

I
 Ese
wy L
CSF (Cerebral Spinal Fluid) Function
Shock absorption: the CSF encasing the brain absorbs the shock so that it does not smack
against the skull.

Nutrition: CSF supplies the central nervous system with essential nutrients, such as glucose,
proteins, lipids, and electrolytes.

Intracranial pressure: A steady flow of CSF keeps the pressure around the brain stable. Too
much CSF, possibly due to a traumatic brain injury or brain tumor, raises intracranial
pressure.

Waste removal: CSF washes through the subarachnoid space, cleaning up toxins and waste
products

Temperature: CSF circulation keeps the temperature of your brain and spine stable.

Immune Function: CSF contains numerous immune cells that monitor the central nervous
system for foreign agents that could damage vital organs.
 CerebroSpinal Fluid

Clear colorless CSF is formed from
the blood plasma by
ultrafiltration through the “blood–
cerebrospinal fluid
barrier” at the choroid plexuses.

Gross visual examination: Normal
CSF is clear, colorless, and
odorless. It has the consistency of
water.

Cloudy indicates infection and/or
inflammation.
https://slideplayer.com/slide/12078519/
 Red line = periosteum
CSF Sampling Sites Blue line = dura mater
Yellow line = arachnoid
arachnoid
Cerebellum
Green line = pia mater
fluid

Sacrum

skull

Cerebellomedullary cistern Sacral cistern (also called lumbar cistern)
CSF Sampling Sites

https://vcahospitals.com/know-your-pet/cerebrospinal-fluid-collection-and-examination
 CSF Sampling Sites - Equine
CSF collection from the
atlantooccipital space requires
general anesthesia.

The atlantooccipital space is
located just caudal to the poll, sedation
on the dorsal midline, at the
level of the wings of the atlas.
The lumbosacral space is usually
accessed in the awake, standing
patient; this avoids the risk of
recovery from general anesthesia.
However, the lumbosacral space is
technically more difficult to enter,
and patients may display violent
reactions to pain from the
procedure. Sedation is needed.
https://veteriankey.com/equine-clinical-procedures/
 Epidural Anesthesia

Used in obstetrics to numb the
pudendal nerve to prevent excessive
straining.

Be especially careful not to pierce the
cauda equina (way too many nerves).

Avoid hitting the venous sinus (blood
vessels within vertebral canal).

Should not inject into CSF (brain
connection).

Avoid femoral, obturator and sciatic
nerves.
 Epidural Anesthesia

http://www.tsvs.net/ www.vcahospitals.com
1. In the dog, the spinal cord ends around what region of
the vertebral canal?

A)Cervical
B)Thoracic
C)Lumbar
D)Caudal/coccygeal
E)Occipital
 2. Which of the meninges is labelled by a star? (4 choices)

A)Pia mater
B)Dura mater
C)Arachnoid
D)Periosteum
o

brain
3. Which of the following is NOT a function of the
Cerebrospinal Fluid (CSF)?

A) Temperature
B) Nutrition
C) Waste removal
D) Immune function
E) Blood flow
Practice Question Answers:

1.C
2.A
3.E
 Vet Prep
Structural and Functional Biology

Dr. Melissa Kehl

Thoracic
Limb
Joints

Courtesy of Dr. Terri Clark
 Learning Objectives:
Describe the bones that make up the shoulder, elbow and carpus.

Describe the important boney prominences / structures that make up these joints.

Utilize scientific terminology necessary to describe these joints movements and directional
terms.

Give examples of muscles which cause action at these joints; as well as their individual origin
and insertions.

Species differences in this lecture are NOT required knowledge at this point; however, they
will be important in the future. Species difference provided in this lecture are only to
encourage critical thinking.
Shoulder or Glenohumeral or Scapulohumeral Joint
tanners scapua humans
laps
 Medial view
Lateral view SCAPULA
spine

intra

c
supra
supra

ip sina.acant acr.si
Left scapula of the dog.
2 - spine; 3 - supraspinous fossa; 4 - infraspinous fossa; 6 - supraglenoid tubercle; 7 - acromion; 12 - glenoid cavity
iseanono.niaseascmoi.vn
strong.my see c avity
t.p.fgien.io
 DOG HUMERUS reactions
arec
arec
resiserie

Left humerus

1 - Greater tubercle lateral
2 – head de
3 - lesser tubercle medial
of
4 - teres major tuberosity medial

5 - deltoid tuberosity Catoid
8 - medial epicondyle
9 – condyle
10 - lateral epicondyle

a no

Caudal view I Cranial view
crackview
and.ie contrias
 Bones of the Shoulder Joint
are
esford
Head of the humerus me

spine
Synovial- ball and socket joint
s
L
cromion

glenoid.it

Glenoid cavity of the scapula
 Shoulder joint
AKA
Glenohumeral joint
AKA
Scapulohumeral joint

“Glenoid”  Greek “Socket”

1 Scapula
5 humerus
6 joint capsule
Shoulder Extension
 Lateral View
Left front

Supraspinatus
cranial

Origin: Supraspinous Fossa

Insertion: Greater Tubercle of Humerus

Action: Extension of the shoulder
Shoulder Flexion
 Medial View fresent
Left front

Teres
Major

Origin:
Caudal border of scapula

Insertion:
Teres Major Tuberosity

Action:
Shoulder Flexion
cranial
caudal
Elbow or Humeroradioulnar Joint
 Elbow joint
3 joints: humeroradial, humeroulnar and proximal radioulnar.
Elbow joint of the dog

5 - Distal humerus
11 - lateral collateral ligament
13 – radius
14 - ulna
15 - joint capsule;
19 - biceps brachii
21 - medial collateral
ligament.
Lateral view
Medial view

ha ha
 cranial view

Radius

Medial
epicondyle condyle

Ulna

cranial view lateral view
 ulna radius Dog

ammar
1 olecranon
2 anconeal process
3 trochlear notch
6 lateral styloid process,
ulna
8 medial styloid process,
radius
9. Condyle of humerus

craniolateral cranial

caudal
cranial
Extension of the elbow
 Lateral View
Left front limb

Triceps Brachii

Origin:
Caudal border of
scapula and proximal
humerus

Insertion:
Olecranon of Ulna

Action:
Extension of the elbow
flex the shoulder
Flexion of the Elbow
 Biceps Brachii

Origin:
Supraglenoid tubercle of
scapula

Insertion:
Radial and Ulnar
Tuberosity (cranial, medial)

Action:
Flex the elbow
Extend the shoulder
Cranial View

Medial
View
Supination Pronation
 Supinator
Origin: Lateral Epicondyle of humerus
Cranial view

Insertion: Cranial radius

Action: Supinate antebrachium (turn
inward)

Pronator teres
Origin: Medial Epicondyle of humerus

Insertion: Cranial radius

Action: Pronate the antebrachium
(turn outward)
Carpal Joint
 Carpal Joints

Antebrachiocarpal joint between the distal radius / ulna and the
carpal bones.

Middle carpal joint between the two rows of carpal bones

Carpometacarpal joint between the distal row of carpal bones
and the metacarpals.
 Flexion of the carpus

A = antebrachial carpal joint; B= middle carpal joint; C = carpometacarpal joint
Flexor carpi ulnaris
Origin:
Medial epicondyle of the humerus and olecranon

Insertion:
Accessory carpal bone

Action:
Flex the Carpus

Caudal View
Left front
 Extension

Carpal Extension Carpal Hyperextension
 Extensor carpi radialis
Origin:
Lateral epicondyle of the
humerus
Extensor carpi radialis
Insertion:
Metacarpal bones II and III

Action:
Dorsolateral Extend the Carpus
View
Left front
 Vet Prep
Structural and
Functional Biology
Pelvic Dr. Melissa Kehl

Limb
Joints

Courtesy of Dr. Terri Clark
 Learning Goals

Describe the actions of muscles on the pelvic limb joints (flexion
and extension) according to the location of the muscles relative to
the joints.

Describe the bones and parts of the bones that form the
coxofemoral joint.

Describe the bones, parts of the bones, and individual joints that
form the stifle joint.

Name and identify the ligaments and structures associated with
the coxofemoral and stifle joints and describe their functions.
Joints of the Pelvic Limb
Sacroiliac jt.

Coxofemoral (hip)
joint

Stifle joint

Tarsus

Metatarso-
phalangeal jts.
Proximal and distal
interphalangeal jts.
 Pelvis

caudal view
 Coxofemoral Joint Lateral view

Ilium
Head of the femur (ball) and acetabulum
(socket) synovial joint
Ischium

Primary movements are flexion and Acetabulum
extension
Pubis
Also allows for abduction, adduction, and
circumduction
Head of
femur

Lateral view Left femur, cranial view
 Flexion and Extension Example
Quadriceps femoris m.
4 heads (only 2 heads
shown)

Origin of rectus femoris :
Ilium

Origin of vastus lateralis:
Proximal femur

Insertion of both: Tibial tuberosity

Tibial tuberosity
Lateral view
Actions of both together:
Flex the hip
Extend the stifle
 partolfeg
caudal

Extension and Flexion Example
Tuber ischii
Semitendinosus m.
A hamstring muscle

Origin:
Pelvis (tuber ischii)

Insertion:
Proximal, caudal tibia
calcaneus
Calcaneus (a tarsal bone)

Actions:
Extend the hip
Flex the stifle Lateral views
Extend the hock
Radiograph of normal canine coxofemoral joints

Femur

Ventrodorsal view
 Joint capsule – fibrous Coxofemoral Joint
outer layer and synovial
inner membrane that
secretes synovial fluid
for lubrication

Ligament of the head of
the femur - courses from
the acetabulum to the
head of the femur

Ventral view

Lateral view
FYI Coxofemoral luxation (dislocation)

Ventrodorsal view
Stifle Joint
Complex condylar synovial joint Stifle Joint
Movements are limited to flexion and extension
Joints:
Femorotibial
Femoropatellar
Proximal tibiofibular
Several ligaments associated with the stifle

Caudolateral view

Cranial view
 Menisci and associated ligaments
Two C-shaped fibrocartilage discs – medial and lateral menisci

Located between the condyles of the femur and the condyles of the tibia

Dorsal view
 Patellar ligament

Tendon of quadriceps
femoris m.
Patella pa

Patellar ligament

Lateral view

Ligament between the patella and the tibial tuberosity
 Collateral ligaments of the stifle

Located on the lateral and medial sides
of the stifle – extra-articular

Help stabilize the stifle

Lateral collateral ligament
Courses from the femur to the fibula and tibia
Limits medial motion of the tibia

Medial collateral ligament
Courses from the femur to the tibia
Limits lateral motion of the tibia
 Cruciate ligaments Stifle of a cat
intra
synovial

Course between the femur and tibia
Intra-articular

Named for where they attach to the tibia

Cranial cruciate ligament
Attaches to the tibia cranially Lateral view
Prevents the tibia from sliding cranially

Caudal cruciate ligament
Attaches to the tibia caudally
Prevents caudal movement of the tibia

Cranial view
FYI
Cranial cruciate ligament rupture

causesa drawl
ofthestifle

Normal cruciate ligaments (left stifle)

Normal caudal cruciate on the right, torn cranial cruciate on the left
 FYI
Cranial cruciate ligament rupture
Diagnosis
Cranial drawer test
Tibial compression test
MRI
Arthroscopy
 Vet Prep
Structural and
Functional Biology
Dr. Melissa Kehl
Axial
Skeleton

Courtesy of Dr. Terri Clark
 Learning Goals

Describe the vertebral formula for the dog.

Describe the features of a typical vertebra.

Describe the difference between vertebral foramen, vertebral canal, and
the intervertebral foramen.

Describe the distinguishing features of vertebrae in each region of the
body.

Describe the joints and ligaments associated with the vertebrae.

Describe the articulation of ribs with vertebrae.

Define axial muscles and explain the difference between epaxial and
hypaxial muscles including their general location and function.
 Skull and mandibles Axial skeleton
Vertebrae
Ribs Vertebral formula for the dog:
Sternum C7 T13 L7 S3 Ca 20-23
Hyoid apparatus
FYI ONLY
T gene mutation of C189G

T box transcription factor T gene
This mutation has been studied in these breeds: Australian Shepherd,
Austrian Pinscher, Brittany Spaniel, Jack Russell Terrier, Karelian Bear
Dog, Schipperke, Spanish Water Dog, Swedish Vallhund, and the
Pembroke Welsh Corgi
Always heterozygous – homozygous expected to be fatal
 Features of a typical vertebra
C7, Caudal view

Vertebral body
Intervertebral discs are located
between adjacent bodies

Vertebral arch Articular process
Consists of pedicles (walls) and
laminae (roof)
Vertebral foramen -
surrounded by arch and dorsal
surface of body where p cord

Processes
(Dorsal) spinous process
Transverse processes – bilateral
Articular processes – cranial
and caudal pairs
 Vertebral canal and intervertebral foramen
Vertebral canal Intervertebral foramen
Formed by the vertebral foramen
Houses spinal cord
Intervertebral foramen between
Located laterally between adjacent
vertebrae
Spinal nerves and blood vessels course
through

Intervertebral foramen

Vertebral canal

Lateral view,
thoracolumbar region
 Cervical vertebrae
C1 and C2 are NOT typical vertebrae!
Atlas, dorsal view

C1 (Atlas)
Large transverse processes, referred to as wings
No spinous process
C2 (Axis)
Prominent spinous process
Dens articulates with atlas

Axis, left lateral view

C1 and C2 craniolateral view
Hants atlas
Joints associated with the Atlas
Atlanto-occipital joint
Between occipital
condyles of skull and the
atlas (C1)
Allows extension and
flexion only (nodding
“yes” joint)

Atlantoaxial joint
Between the atlas (C1)
and the axis (C2)
Rotary movement along
the long axis (“no” joint) www.reddit.com
 Ligaments associated with the atlas and axis
Several ligaments stabilize the atlas and axis.

Transverse ligament of the atlas - holds dens against the atlas
 Vertebral a.
Cervical vertebrae

C3-C6 C5, Craniolateral
view
More typical
Short spinous processes
Transverse foramen present
in transverse processes of C1-
C6 for vertebral artery, vein,
nerve in systemotherthan c
not

C7
No transverse foramen
Has a costal fovea for
articulation with the 1st rib C7, Caudal view
 Lateral radiograph of cervical vertebrae
Dog

FYI
 Thoracic vertebrae

Long spinous processes

Short transverse
processes due to
articulation with ribs

Costal foveae on bodies
and transverse
processes for
articulation with ribs

T6, craniolateral view
 Ribs and Sternum
13 pairs of ribs in the dog
8 sternebrae in the dog

Costochondral junction
Junctionwhereribs
thecartilage
meet

Costal Cartilage
FYI

Flat Chested Kitten Syndrome

Kittens with flat chests have a thoracic deformity and is characterized
by sharp angulation at the costo-chondral junction causing marked
dorso-ventral (top to bottom) flattening of the rib cage.
 Tubercle of rib
Rib articulation T4 T5
Head of rib
The head of the rib articulates with
the body of the corresponding
thoracic vertebrae. Transverse process
For ALL ribs, the head of the rib
Body
articulates with the body of the
same number.
For ribs 1-10, the head of the rib
ALSO articulates with the body of
the vertebrae cranial to it.
ai
The tubercles of the ribs articulate
with the transverse processes of the
corresponding vertebrae for ALL Rib 5
ribs.
 Lumbar vertebrae
Large bodies
Large transverse processes
Prominent spinous processes T13
Extra processes for muscle Sacrum

attachment
 Sacrum

Fused S1, S2, S3
vertebrae Ventral view
Articulates with ilium
Fused transverse
processes
Sacral foramen for
nerves instead of
intervertebral foramina Dorsal view
(3, 3’) dyingIsdtogether

Cranial view

2. Articular surface 3. Ventral (3’ dorsal) sacral foramina
4. Spinous process 6. Vertebral canal 7. Body
 Caudal/coccygeal vertebrae
First few caudal vertebrae look like typical vertebrae and then they
become more rod-shaped
Hemal arch located on Ca4-Ca6 - Protects tail vessels

Ca5
 Intervertebral disc
 Located between vertebral
bodies (except at C1-C2 and in
the sacrum)

 Two parts:
1. Anulus fibrosus
Outer circumferential
collagenous fibers
Thicker ventrally
2. Nucleus pulposus
Inner gelatinous core

 Shock absorber, spreads the
load evenly between bones
FYI
Intervertebral Disc Disease
acute chronic
Is cord
me

_ spinal
 Vertebral ligaments
Supraspinous ligament

Courses dorsally along the spinous processes
of T1 – Ca3 vertebrae

Nuchal ligament
Cranial extension of the supraspinous ligament
Courses between the spinous processes of the
axis (C2) and T1 in the dog (more extensive in
large animals!)
Not present in the cat or pig

Nuchal ligament Supraspinous ligament

smashiTames
See you in week 5!
Preheat

Dr. Cristian Martonos 1
Previous lecturer: Dr. Cristian Dezdrobitu
“The right half of the brain controls the left half of
the body. This means that only left handed
people are in their right mind.”
https://www.pinterest.com/pin/565483296946963803/

!!! ‘’Pathways of nerve impulses
are crossed pathways — meaning
that the Left side of the brain
controls the RIGHT side of the
body, and the Right side of the
brain controls the LEFT side of the
2
body’’ !!!
 3
https://www.slideshare.net/wyllhy/the-nervous-system-slide-show
4
Role:

controls and coordinates all essential functions of the body

in the smooth functioning of the different parts of our body

without the nervous system we wouldn't be able to think,
feel, move or survive

the most important function of the nervous system is to
integrate and respond to the environment 5
‘’The detection of environmental changes, their subsequent
integration and interpretation, and finally, the production of
a behavioral response are the function of the nervous
system, incomparably the most complicated of the body
systems.’’
DYCE, SACK AND WENSING’S TEXTBOOK OF VETERINARY ANATOMY,
FIFTH EDITION ISBN: 9780323442640

6
Function:
SENSORY
sensory receptors used to monitor changes both inside and
outside of the body

gathered informations : Sensory input
7
Function:
INTEGRATIVE
process and interprets the sensory input and takes decisions
about what should be done - INTEGRATION

MOTOR
NS sends informations to the effectors (muscle, glands,
internal organs)

8
 DYCE, SACK AND WENSING’S TEXTBOOK OF VETERINARY ANATOMY,
FIFTH EDITION ISBN: 9780323442640

A simplified receptor: effector neural circuit. 1. Skin receptor; 2, afferent or
sensory neuron; 3, synapses on interneuron; 4, interneuron; 5, efferent or motor 9
neuron; 6, striated muscle (effector).
10
DYCE, SACK AND WENSING’S TEXTBOOK OF VETERINARY ANATOMY,
FIFTH EDITION ISBN: 9780323442640

cervicaln erves
sacralnerves

11
 Brain and spinal cord act like the integrating and
command center of the nervous system.

Role:
to interpret incoming sensory information and issue
instructions based on past experience and current
conditions

12
Outside the CNS

Carries impulses from the sensory receptors to the
CNS and from the CNS to effectors

Cranial nerves: to and from the brain
Spinal nerves: to and from the spinal cord

13
Divided functionally in:
afferent division (also termed the
sensory component, conducts
impulses toward the spinal cord and
brain)

efferent division (or motor
component of the peripheral nervous
system conveys impulses away 14from
the brain and spinal cord)
Afferent and Efferent

subdivided into the SOMATIC and VISCERAL
systems

15
Somatic system

is concerned with both sensory and motor
functions that determine the relationship of the
organism to the outside world

they include detection of stimuli
in the skin
in the tissues of the limbs and trunk 16
behavioral actions such as locomotion
Somatic system

is sometimes referred to as the voluntary system,
because there is a greater conscious awareness
and greater voluntary control of somatic
functions than of the visceral functions

17
Visceral system

concerned with sensory and motor functions
that relate to the internal viscera. E.g: the
regulation of the blood pressure and heart rate,
the control of glandular activity and digestive
processes
the motor component of the visceral peripheral
nervous system is also referred to as18the
autonomic nervous system
 Autonomic nervous system:
Sympathetic
Parasympathetic
Most organs receive innervation from both components. The sympathetic and
parasympathetic components are often described as having antagonistic
actions on each organ, although “balancing” might better describe their
cooperative role.
Visceral efferent fibers of the sympathetic division leave the central nervous
system via the spinal nerves in the thoracolumbar regions of the spinal cord;
those of the parasympathetic division are found in a small group of cranial
nerves (III, VII, IX, X) and in spinal nerves in the sacral region of the spinal cord.
Many visceral efferent fibers travel to their target organ by joining with19other
nerves so that they obtain a very widespread peripheral distribution.
Somatic Nervous System Autonomic Nervous System
Regulates the voluntary movement Regulates the involuntary movement
of the body of the body
Regulates movements of the body
Regulates bodily functions such as
via the skeletal muscles, along with
respiratory rate, heart rate, urination,
sensory stimuli related to vision, smell,
digestion, sexual arousal, pupillary
taste, pain, noise, touch, and
response
temperature
Made up of the afferent nerves Made up of a complex network of
(sensory nerves) and efferent nerves motor neurons, which control glands,
(motor nerves) that stimulate skeletal cardiac muscles, and smooth
muscle movement muscles
Divisions include the sympathetic
Divisions include the spinal nerves
and the parasympathetic nervous
20
and the cranial nerves
system
 21
https://www.slideshare.net/wyllhy/the-nervous-system-slide-show
 DYCE, SACK AND WENSING’S TEXTBOOK OF VETERINARY ANATOMY,
FIFTH EDITION ISBN: 9780323442640

Neurons (nerve cells) are the basic elements of
the nervous system.
22
 Thin branching
extensions of
the cell body
that conduct
nerve impulses
toward the cell
body
Courtesy of Drs Ray Wilhite, Dan Hillmann and Joe Rowe

https://www.slideshare.net/itutor/nervous-system-22589837
A single branch (in
most neurons) which
conducts nerve 23
impulses away from
the cell body.
spinalnervesaremixednerve
have
ftp.mf Pffrasympanetic

CROSS
SECTION
OF
SPINAL 24
CORD
 DYCE, SACK AND WENSING’S TEXTBOOK OF VETERINARY ANATOMY,
FIFTH EDITION ISBN: 9780323442640

Dorsal view of the
spinal cord and the
vertebral pedicles of
the horse. The spinal
cord is shorter than the
vertebral canal
(ascensus medullae
spinalis). (B)
Enlargement of the
caudal part. 1, Atlas; 2,
ilium; 3, sacrum; 4,
cervical intumescence;
5, lumbar 25
intumescence; 6,
cauda equina.
 NERVES

Based on the direction of the nerve impulse,
there are:

Sensory (afferent) nerves

Motor (efferent) nerves

Mixed nerves = sensory + motor (somatic and/or autonomic)
26
Based on the site of emergence, there are:
Spinal nerves (emerge from the spinal cord)
Cranial nerves (emerge from the brain)

NOTE!
A