General Osteology_ 2024 1 (1).pdf

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General osteology
Department of Anatomy
Jessenius Faculty of Medicine in Martin
Comenius University Bratislava

Ac. year 2024/2025
Human skeleton – around 10% of body weight

axial skeleton
vertebral column
ribs, sternum
skull

appendicular skeleton
skeleton of the upper limb
skeleton of the lower limb
Functions of the human
skeleton:
support, movement

protection of vital organs

haematopoiesis - blood cell
production

metabolism of minerals (reservoir
of calcium and phosphorus)

endocrine function
Functions of the human
skeleton:
support - internal framework which
mechanically supports the body

movement - allowed by the joints
between the bones and powered by the
muscles attached to the bones

protection of vital organs

- skull - the brain

- thoracic skeleton - the lungs and the heart
with large vessels

- vertebral canal - the spinal cord,
Functions of the human skeleton:
haematopoiesis - blood cell development in the bone
marrow
bone marrow - gelatinous substance within the spongy bone; it
contains blood stem cells - responsible for the generation of
blood cells and marrow adipose tissue
depending on the prevalence of hematopoietic cells vs marrow adipose tissue

✓ red marrow (medulla ossium rubra)
hematopoietically active https://www.cancer.gov/publications/dictionaries/cancer-terms/def/bone-marrow

in adults only in vertebrae, skull, sternum, ribs, hip bones and
at the epiphyses of the long bones
✓ yellow marrow (medulla ossium flava)
made mostly of fat - marrow adispose tissue
not found in children until cca 7 years
then progressive conversion towards "yellow" marrow with the age
https://www.mybeckman.co/resources/sample-type/tissues/bone-marrow
 Functions of the human skeleton:
metabolism of minerals - reservoir of endocrine function

calcium and phosphorus - osteoblasts release the hormon

- 99% of body calcium and 30% of body phosphorus osteocalcin - bone-specific protein
reserves - bound in the bones

- bone marrow - iron metabolism - haemoglobin

https://labs.selfdecode.com/blog/osteocalcin/

Schalin-Jäntti, Camilla. (2019). Unmet therapeutic, educational and
scientific needs in parathyroid disorders. European journal of
endocrinology. 181. 10.1530/EJE-19-0316.
Bone
organic substances – cells (osteocytes, osteoblasts, osteoclasts) and
collagen typ I
inorganic matrix – calcium phosphate, magnesium
phosphate,calcium carbonate...
collagen fibrils are encased within calcium phosphate crystals

Macroscopic architecture - 2 forms:
Sangchay, Napakorn. (2015). Impact of nitric acid exposure on

compact (cortical) bone – outer layer
the morphometrix analysis of osteon.

- osteons and lamellae (see next slide)
- at the epiphysis – thin shell
- at the diaphysis - thick

spongy (cancellous or trabecular) bone
- trabeculae – long slender protrusions
- no true osteons
- less density (5-70% of compact bone) spongy
(cancellous or trabecular)
- spongy bone in flat bones of the skull bone
is called „diploe“ http://histology.med.yale.edu/bone/bone_reading.php Sangchay, Napakorn. (2015). Impact of nitric acid
exposure on the morphometrix analysis of osteon.
 Compact and spongy bone
compact (cortical) bone spongy (cancellous or trabecular)
bone
- Haversian system – osteons 3 types of cells are responsible for
the bone homeostasis: - branched protrusions - trabeculae,
- osteon - concentrinc rings osteoblasts - producing the osteocytes within the bone matrix,
(lamellae) of bony tissue bone matrix, when they are bone marrow within irregular
around the central entrapped in the lacunae - cavities formed by trabeculae
„Haversian“ canal containing become osteocytes
the blood and lymphatic - trabeculae of spongy bone follow
osteocytes - mature bone cells
vessels and nerves the lines of mechanical stress and
osteoclasts - resorbing the
they can realign due to stress
bone
changes

osteon

http://histology.med.yale.edu/bone/bone_reading.php http://histology.med.yale.edu/bone/bone_reading.php
Sangchay, Napakorn. (2015). Impact of nitric acid exposure on
the morphometrix analysis of osteon.
 Bone modeling and remodeling
osteogenesis (bone formation) –performed by the osteoblasts
osteoclasis (bone resorption) – performed by the osteoclasts
bone modeling – osteogenesis and osteoclasis at the different sites – the shape of the bone changes
bone remodeling - osteogenesis and osteoclasis at the same site – the shape of the bone is not
changed but the old bone is replaced by the new bone
in constant loading of bones - osteogenesis and osteoclasis are in balance
osteogenesis ˃ osteoclasis... osteosclerosis
osteogenesis < osteoclasis...osteolysis or osteoporosis

https://www.osc-ortho.com/blog/what-are-osteoporosis-osteopenia/
http://histology.med.yale.edu/bone/bone_reading.php https://musculoskeletalkey.com/osteosclerosis/
Periosteum
covers the outer surface of the bones except the articular surfaces (they are covered by
articular cartilage)
it consists of 2 layers:
outer – fibrous layer – dense connective tissue and fibroblasts
inner – osteogenic regenerative layer - progenitor cells → osteoblasts
– this layer is responsible for:
- the growth of the bone in the width (appositional growth)
- regeneration (healing process e.g. after the fracture)
periosteum is highly vascularized (periostal vessels) and very well innervated (high density of
the sensory nerve fibres)
Sharpey fibres anchor the periosteum to the compact bone

Illustration from Anatomy & Physiology,
Connexions Web site.
http://cnx.org/content/col11496/1.6/, Jun 19,
2013.
 Endosteum
endosteum covers the surface of the spongy bone –
trabeculae and the Haversian canals
it is formed by a single layer of the epithelial cells
it is much thinner than the periosteum

R.K. FUCHS, S.J. WARDEN, C.H. TURNER,2 - Bone
anatomy, physiology and adaptation to mechanical
loadingEditor(s): Josep A. Planell, Serena M. Best,
Damien Lacroix, Antonio Merolli,In Woodhead
Publishing Series in Biomaterials,Bone Repair
Biomaterials,Woodhead Publishing2009,Pages 25-
68,ISBN
9781845693855,https://doi.org/10.1533/978184569661
http://histology.med.yale.edu/b
0.1.25.
one/bone_reading.php
 Classification of the bones

long bones
flat bones
short bones
irregular bones
air filled bones
sesamoid bones

https://biology-forums.com/index.php?action=gallery;sa=view;id=8947
 Long bones
shaft (body; corpus in Latin) – diaphysis
proximal end - proximal epiphysis
distal end – distal epiphysis
metaphysis between the epiphysis and diaphysis
apophysis – elevation, protrusion at the bone with separate
ossification centre
epiphysial plate or growth cartilage
- responsible for the longitudinal growth of the long bones
- around 20 years of age, the cartilage is replaced by bony
tissues
medullary cavity within the shaft (in adult - yellow bone
marrow)
https://www.theskeletalsystem.net/types-of-bones/long-bones

humerus, femur, radius, ulna, metacarpal bones,
phalanges...
not the size, however, the shape is important
phalanges are miniatur long bones - they have diaphysis - shaft
and 2 epiphyses - head and base
https://www.mybeckman.co/resources/sample-type/tissues/bone-marrow
Flat bones Short bones
layer of spongy bone between two thin no medullary cavity but a core of spongy
layers of compact bone bone

scapula, frontal bone, parietal carpal bones – scaphoid,
bone, sternum, ribs, ilium... trapezium...
tarsal bones – talus, calcaneus...
Irregular bones Air - filled bones
(pneumatic bones)
vertebra, sacrum,ethmoid bone,
mandible... frontal bone, sphenoid bone,
maxilla, mastoid process of
temporal bone, ethmoid bone...
Sesamoid bones
bones embedded in tendons
patella, pisiform bone...

patella
Blood supply
of the bones
https://3d4medical.com/blog/blood-supply-to-the-bone

Nutrient artery system (arteriae nutritiae)
nutrient arteries are branches from major systemic
arteries
artery runs into the bone through the nutrient
foramen to the medullary cavity
supplies cca 2/3 of the bone within Haversian
system (osteons)
Metaphyseal-epiphyseal system
epiphyseal and metaphyseal arteries from the
arteries around the joint – periarticular plexuses
Periostal system
periostal arteries (from periosteum) supply outer
1/3 of the bone
Bone development endesmal
enchondral

- begins since the end of the 2nd embryonic month
- ends around 20years of age
- 2 types of ossification – osteogenesis: endesmal and enchondral
Endesmal
(intramembranous)
ossification
direct conversion of embryological
mesenchymal tissue - membranes to
the bony tissue
mesenchymal cells differentiate
directly to the osteoblasts
flat bones of the skull (e.g. parietal
bones, frontal bone...)
http://histology.med.yale.edu/bone/bone_reading.php
Čihák, R.: Anatomie 1. Grada, 2011.
 endesmal
Bone development enchondral
- begins since the end of the 2nd embryonic month
- ends around 20years of age
- 2 types of ossification – osteogenesis: endesmal and enchondral

Enchodral (cartilagineous)
ossification
indirect
bone is synthetized from the hyaline
cartilage
mesenchymal cells firstly differentiate to
the chondrocytes that proliferate, produce
the matrix and form the cartilagineous
model of the bone;
subsequently the cartilagineous template
of the bone is rebuilt to the bony tissue
majority of the bones – e.g. long
bones... http://histology.med.yale.edu/bone/bone_reading.php Čihák, R.: Anatomie 1. Grada, 2011.
Ossification centres
Primary ossification centres
appear during the first half of the
intrauterine development (the first
centres cca in the 8. – 9. embryonic
week)
situated in the diaphyses of the long
bones or at the bodies of the irregular
bones
Secondary ossification https://radiopaedia.org/articles/diaphysis

centres
?lang=us

emerge during the 2nd half of the
intrauterine development and
postnataly during the first years
situated in the epiphyses and
apophyses (epiphyseal and Mikael Häggström,
from source image by
apophyseal ossification) James Heilman -
File:Tibfracture.png
Appearance of ossification centres

Skeletal development of the hand. Schematic
representation (source: Schmitt and Lanz 2008).
https://radiologykey.com/skeletal-age/

Determination of the skeletal age (skeletal maturity)
– the most common method - wrist X ray – reflects
maturity of the carpal bones – important e.g. for the
orthopedics – treatment planning
references
Paulsen, F. et al. Sobotta Anatomy Textbook, Elsevier Science, 2018. 840 s. ISBN 9780702067600.

Paulsen, F. et al. Sobotta Atlas of Human Anatomy, (3 Volume Set), Urban and Fischer, 2013. 1180 s. ISBN 9780702052507. English Edition with English Terminology

Drake, R. wt al. Gray´s Anatomy for Students, 4th Edition. Elsevier Science, 2019, 1180 pp. ISBN 9780323393041

Song L. Calcium and Bone Metabolism Indices. Adv Clin Chem. 2017;82:1-46. doi: 10.1016/bs.acc.2017.06.005. Epub 2017 Aug 7. PMID: 28939209.
Sangchay, Napakorn. (2015). Impact of nitric acid exposure on the morphometrix analysis of osteon.
http://histology.med.yale.edu/bone/bone_reading.php
Schalin-Jäntti, Camilla. (2019). Unmet therapeutic, educational and scientific needs in parathyroid disorders. European journal of endocrinology. 181. 10.1530/EJE-19-0316.
https://www.osc-ortho.com/blog/what-are-osteoporosis-osteopenia/
https://musculoskeletalkey.com/osteosclerosis
Illustration from Anatomy & Physiology, Connexions Web site. http://cnx.org/content/col11496/1.6/, Jun 19, 2013.
R.K. FUCHS, S.J. WARDEN, C.H. TURNER,2 - Bone anatomy, physiology and adaptation to mechanical loadingEditor(s): Josep A. Planell, Serena M. Best, Damien Lacroix, Antonio Merolli,In
Woodhead Publishing Series in Biomaterials,Bone Repair Biomaterials,Woodhead Publishing2009,Pages 25-68,ISBN 9781845693855,https://doi.org/10.1533/9781845696610.1.25.
https://biology-forums.com/index.php?action=gallery;sa=view;id=8947
https://www.theskeletalsystem.net/types-of-bones/long-bones
https://3d4medical.com/blog/blood-supply-to-the-bone
Schmitt and Lanz 2008 : Skeletal development of the hand. Schematic representation. https://radiologykey.com/skeletal-age/
Čihák, R.: Anatomie 1. Grada, 2011.