Unit 2: Skeletal System PDF

Summary

This document is a presentation on the skeletal system. It gives information on the objectives, bone types (long, short, flat, irregular), bone structure (compact and spongy), bone cells (osteoblasts, osteocytes, osteoclasts), bone matrix, and calcium homeostasis. It features diagrams and explanations for a better understanding.

Full Transcript

Unit 2: Skeletal System
Devin Mott PT, DPT
Objectives
Compare and contrast osteoblasts and osteocytes
Identify major long, short, flat, and irregular bones in the body
Describe the process of Ca regulation in the body
Bird’s Eye View
Bones are the scaffolding of the body with many functions
○ Providing shape
○ Allowing for motion
○ Protection of organs
○ Cell production in bone marrow
In total an adult has about 206 bones
Gross Bone Anatomy
Basic Bone Anatomy (1 of 2)
Periosteum is a tough and fibrous connective tissue that
covers bone.
○ Contains blood vessels that transport blood and
nutrients to nurture bone cells
○ Contains lymph vessels and nerves
○ Acts as an anchor point for ligaments and tendons
Basic Bone Anatomy (2 of 2)
Epiphysis: end of a long bone
Diaphysis: region running between the two epiphyses.
○ Medullary cavity: hollow within the diaphysis that
stores yellow marrow
○ Yellow marrow has a high fat content and can convert
to red marrow, which makes red blood cells, in an
emergency.
Figure 6–2
Bone Tissue (1 of 3)
Compact bone
○ Dense, hard, tightly packed tissue
○ Found in shafts of long bones and outer layer of other
bones
○ Contains units called osteons (haversian systems)
Contain mature bone cells (osteocytes) that form
concentric circles around a central (haversian)
canal, containing blood vessels
Bone Tissue (2 of 3)
Osteons run parallel to each other with perforating canals
(blood vessel passages) literally connecting with them to
ensure sufficient oxygen and nutrients for the bone cells.
Bone Tissue (3 of 3)
Spongy (cancellous) bone
○ Arranged in bars and plates called trabeculae
○ Irregular holes between trabeculae make the bone
lighter and provide space for red bone marrow, which
produces red blood cells
Bone Cells
Osteoprogenitor Cells
Osteoblasts
Osteocytes
Osteoclasts
Bone Lining Cells

https://app.jove.com/embed/player?id=14011&t=1&s=1&fpv=1
Osteoprogenitor Cells
Osteoprogenitor cells
– Non-specialized
▪ Can turn into other cell types as needed
– Found in periosteum, endosteum, and central canal of
compact bones
Osteoblasts
Responsible for the construction of osteoids
○ Mature from mesenchymal stem cells
Regulation from parathyroid hormone and vitamin D
Mature osteoblasts are responsible for protein synthesis
Q: What do we expect there to be a large amount of?
○ Osteoid: found in areas of new bone formation
Converts to mature mineralized bones
Osteocytes
Most abundant bone cell
Connect via tunnels called canaliculi
○ Allows for communication
○ Canaliculi serves for movement of nutrients and waste disposal
Responsible for mechanosensing and responding to strain
Osteoclasts
Responsible for reabsorbing mineralized bone
○ Pumps carbonic acid and enzymes to degrade the bone
○ Activated by osteoblast activity
This coupling is important for calcium regulation

https://app.jove.com/embed/player?id=12519&t=1&s=1&fpv=1

https://app.jove.com/embed/player?id=12520&t=1&s=1&fpv=1
Bone Lining Cells
Old osteocytes that no longer play a role in synthesis
○ Flat and thin with little activity
When the bone lining cell peels back osteoclasts are stimulated for
reabsorption
Bone Matrix
Osteoid
○ Immature bone matrix (not yet mineralized)
Bone Collagens (type of protein)
○ Bone is mostly Type 1 collagen
○ Gives bone its rigid structure
Extracellular Matrix
○ Mostly made of mineral
Calcium and phosphate
○ Gives bone mechanical properties

https://app.jove.com/embed/player?id=12520&t=1&s=1&fpv=1
Bone Types
Long
Short Bones
Flat Bones
Irregular Bones
Long Bones
Long shaft with two bulky ends
○ Predominantly compact bone however have a large amount of spongy bone at the ends
Three distinct zones:
○ Epiphysis
Region at end of bone
Allows attachment site at joints
○ Metaphysis
Transitional area
Attachment site of most tendons
○ Diaphysis
Center: primarily a structural function
○ In development epiphyseal plate is a fourth zone

https://app.jove.com/embed/player?id=10864&t=1&s=1&fpv=1
Epiphyseal Plate
Responsible for longitudinal
growth
Cells replicate in the zone of
proliferation
Active during stages of growth
○ Stops somewhere between 18-21
Short Bones
Formed in similar manner to long bones
Vary in shape and size
Cube shape and primarily spongy bone
Flat Bones
Cortical shell and stiff interior
Broad and flat
○ Major focus is on providing protection or flat surface for attachments
Irregular Bones
Primarily spongy bone
Bones of the spine
Compact and Spongy Bone
Compact:
○ Denser and stronger tissue
○ Makes up the outer cortex
○ Made up of Osteons (Haversian
System)
Spongy (Cancellous)
○ Trabeculae in place of Haversian
System
○ Lined with endosteum
○ Makes bone lighter and gives space
for red bone marrow
Gross Bone Anatomy
Diaphysis:
○ Medullary cavity filled with bone marrow
○ Outer wall composed of dense hard compact
bone
Epiphysis:
○ Filled with spongy bone
○ Covered in hyaline cartilage
Bone Anatomy
Periosteum
○ Tough and fibrous tissue covering
bone
○ Provides anchor points for
ligaments
Bone Marrow
○ Red: makes blood cells
○ Yellow: High in fat
Blood and Nerve Supply
Arteries enter through nutrient
foramen
○ Serves the spongy bone and
medullary cavity
Nerve follows similar pathways
Calcium Homeostasis
Regulated by PTH, Vit. D and Calcitonin
Low Calcium:
○ PTH: role is to increase serum levels of calcium
Increases kidney’s ability to convert Vit. D to active form
Stimulates osteoblasts resulting in upregulation of osteoclasts
High Calcium
○ PTH is down regulated and Calcitonin is released to down regulate osteoclast

https://app.jove.com/embed/player?id=14023&t=1&s=1&fpv=1
Coupling and Remodeling
Role is to keep bone strong and heal damage
Dual Regulation
○ Local
Mechanical Strain, variety of proteins
○ Systemic
Vit. D, PTH, calcitonin
Uncoupling:
○ Goal is for absorption and formation to reach homeostasis
Need for serum Ca outweighs the need for coupling
Coupling Signals
Matrix Derived Factors
○ Bone matrix stores a variety of growth factors including platelet derived growth
factor and insulin like growth factors
Factors are deposited by osteoblasts during matrix production and released
by osteoclasts
Main influence: stimulation of osteoblast progenitors
Osteoclast Secreted Factors
○ Contain anti-resorptive inhibitors: may reduce bone resorption without impacting
bone formation
Osteoclast Membrane Bound Factors
○ Osteoclasts interact directly with mature osteoblasts to promote their activity
Coupling Mechanisms
There are different ways that bone breakdown (resorption) and bone formation can be
linked, even though they don’t happen at the same time. These are possible mechanisms
that help coordinate the process:

1. Osteoclast signals: Osteoclasts (cells that break down bone) release signals
that trigger early bone-forming cells (osteoblasts) to start developing. Other
signals from nearby cells in the bone unit help fine-tune the number and activity
of these bone-forming cells.
2. Support from other cells: Some cells help pass along these signals to both
developing and mature osteoblasts. These include:
○ (B) Cells that are already in the osteoblast family and are located in
the protective layer over the remodeling bone.
○ (C) Reversal cells, which are found on the bone surface and help
prepare for new bone formation.
○ (D) Osteocytes, which are mature bone cells embedded in the bone
that help communicate about bone changes.
3. Physical changes: The physical changes made by osteoclasts, such as the
pits they create in the bone or mechanical stress sensed by osteocytes, send
additional signals to make sure the right amount of new bone is made by mature
osteoblasts.

The timing for each of these steps has been observed in bone samples from adult
humans.
Growth and Repair (Osteogenesis)
Bone modeling starts at about 8 weeks after conception
○ Bone will start to replace cartilage
○ Primary Ossification:
Happens in utero
○ Secondary Ossification:
Starts around birth
Growth will continue as long as growth plates are present
Wolff’s Law
Bone’s model and remodel in response to mechanical environment
○ Osteocytes sense mechanical signals and will mediate osteoclasts and osteoblasts
in their vicinity

https://www.youtube.com/watch?v=FlATeMqTH2g