Skeletal System II PDF

Summary

This document discusses the skeletal system, focusing on bone marrow, bone development (intramembranous and endochondral ossification), and bone remodeling. It also touches upon calcium homeostasis. Key concepts like osteoblasts, osteocytes, and chondrocytes are highlighted.

Full Transcript

BIOL 116
Skeletal System II

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Bone Marrow

Occupies - cavities of long bones & small spaces within spongy bone

Red marrow (hematopoietic tissue)
Reticular tissue, capillaries and hematopoietic cells (give rise to RBC, WBC
& platelets)
Located in nearly all children bones
Adults (skull, vertebrae, ribs, sternum, pelvic girdle, & proximal heads of
humerus and femur)

Yellow marrow found in adults
Reticular tissue accumulates fat and transforms into adipose cells
Fatty marrow that does not produce blood
Can transform back to red marrow in the event of chronic anemia

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Bone Development – Formation of Bone

Ossification or Osteogenesis - formation of bone

In the human fetus and infant, bone develops by two methods;

Intramembranous ossification
Produces flat bones of skull, mandible & clavicles
Thickens long bones throughout life

Endochondral ossification
Bone grows from pre-existing model composed of hyaline cartilage
Begins at around 6-8 weeks of fetal development and continues to 20s

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Intramembranous ossification

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Intramembranous ossification
Step 1
Process begins in mesenchyme tissue
Mesenchymal cells cluster around blood islands forming ossification center (site where bone
develops)
Mesenchymal cells → osteoprogenic cells → osteoblasts
Osteoblasts secrete organic extracellular matrix called osteoid (uncalcified matrix)

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Intramembranous ossification
Step 2
Calcification begins - calcium & minerals crystalize on top of collagen fibers
Osteoblast become trapped and become osteocytes (within lacunae)
At the edge of growing bone - Osteoprogenic cells differentiate into new osteoblasts

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Intramembranous ossification
Step 3

Ossification continues and forms thin immature
spongy branches (spicules)
Spicules touch and grow around existing
blood vessels – eventually forming trabeculae
of spongy bone

Mesenchymal cells differentiate and give rise to
surrounding periosteum

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Intramembranous ossification
Step 4
Osteoblasts beneath periosteum fill in trabeculae &
reorganize as osteons - layer of compact bone on
each side
Spongy bone matures and fills with red bone
marrow

Flat bones have a sandwich of
Compact/Spongy/Compact

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Endochondral Ossification

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Endochondral ossification
Replacement of Cartilage by Bone

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Endochondral ossification
Developing in Cartilaginous Model

Mesenchymal cells differentiate into chondroblasts &
fibroblasts
Chondroblasts secrete extracellular matrix
Once trapped chondroblasts → chondrocytes
Fibroblasts creates the perichondrium.

Bone model grows via appositional/interstitial growth

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Endochondral ossification
Step 1

1. Mesenchymal cells of the perichondrium further
differentiate into osteoblasts (begin to calcify the
matrix)

Osteoblasts secrete osteoid bone collar cutting off
nutrients from chondrocytes

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Endochondral ossification
Step 2

2. Chondrocytes die, leaving spaces (cavities)

Matrix calcifies blocking nutrient supply to chondrocytes
Deep chondrocytes hypertrophy (enlarge) and undergo
apoptosis (die)

Primary ossification center forms.

Chondrocytes die, leaving space (cavity)
Cavity weakens model but collar stabilizes it

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Endochondral ossification
Step 3

3. Periosteal bud
Nutrient artery passes through perichondrium (via nutrient
foramen) and enters the cavity
Stimulates cells in perichondrium to differentiate into
osteoblasts forming periosteum

Osteoblasts move in and replace the calcified cartilage with
osteoid forming spongy bone
Osteoclasts remodel diaphysis to create medullary cavity

Surrounding bone will be replaced by compact bone

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Endochondral ossification
Step 4
4. Bone elongates & medullary cavity enlarges as
osteoclasts breakdown newly formed spongy bone in
diaphysis

Epiphysis are made of cartilage which allows the bones to
elongate through the mitotic division of chondrocytes

At birth most long bones have a bony diaphysis and two
cartilaginous diaphysis

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Endochondral ossification
Step 5

5. Before/after birth branches of the epiphysial artery invade the
epiphysis, giving rise to the secondary ossification center (no
medullary cavity formed)

Hyaline cartilage covering epiphysis develops into articular cartilage
Hyaline cartilage between epiphysis & diaphysis remains as the
epiphyseal growth plate (lengthwise growth)

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Endochondral Ossification
Bone elongation

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Bone Remodeling

Absorption & Deposition - occurs throughout life - 10% of skeleton per year
Remodeling is a collaboration between action of osteoblasts and osteoclasts
Repairs microfractures, releases minerals into blood, reshapes bones in
response to use & disuse

Wolff’s law of bone: architecture of bone is determined by the presence or
absence of mechanical stresses placed on bone
Bony processes grow larger in response to mechanical stress

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Calcium Homeostasis

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