Download The Biomechanics of the Human Spine

The Biomechanics of the
Human Spine
Biomechanics and ergonomics-Chapter 9
Structure of the Spine

33 vertebrae structurally divided into
five regions:
cervical
region - 7
vertebrae
thoracic
region -12
lumbar
region - 5
sacrum
- 5 fused
coccyx
- 4 fused
Structure of the Spine

The motion segment, consisting of two adjacent
vertebrae and the associated tissues, is considered to
be the functional unit of the spine.
Structure of the Spine

Verterbral bodies act as primary weight bearing
components of spine

The spinous and transverse processes improve
the mechanical advantage of attached muscles.

Atlantooccipital joint is extremely stable (14-15ᵒ
flexion/extension)

Atlantoaxial joint permits 75ᵒ rotation,14ᵒ
extension and 24ᵒ lateral flexion
Orientation of facets
Structure of the Spine

Progressive increase in vertebral size from
cervical through lumbar region.

Increased surface area of lumbar spine reduces the
stress

Contact forces are largest at L5-S1
Structure of the Spine
What types of joints connect adjacent vertebrae?

Intervertebral symphysis joints on the
anterior side

Two gliding diarthrodial facet joints on the
posterior side
Structure of the Spine
What is the function of the facet joints?
• To channel and limit the range of motion in the
different regions of the spine
• To assist in load bearing, particularly when the spine
is in hyperextension and disc degeneration has
occurred
Structure of the Spine

Facet joints and discs provide about 80% of
spine’s ability to resist rotational torsion and
shear with half contribution from facet joints.
Intervertebral disc

Intervertebral discs consists of:
 Nucleus
pulposus a colloidal gel
 Annulus
fibrosus, a thick, fibrocartilaginous ring
that forms the disk exterior.

Annulus is more sensitive to rotational stresses.

Nucleus is 90% water

High fluid content makes nucleus resistant to
compression
Intervertebral disc
Intervertebral disc

Mechanically, annulus
behaves as a coiled spring ,
holding vertebral bodies
together, whereas nucleus
puposus acts as
incompressible ball bearing
that the vertebra roll over
during flexion/extension and
lateral flexion
Intervertebral disc

IVD contributes to 1/4th of spinal height

When disc is loaded in compression it loses water
and absorbs ions.

Over the coarse of a day spine loses its height up to
2cm.

54% of this loss occurs in first 30 minutes after
getting up in the morning.

Disc height and volume are greatest when a person
wakes up in the morning
Point to ponder

Astronauts experience a temporary increase in
height of 5cm.why?
Because of no compression on disc due to earth’s
gravity.
Intervertebral disc

Spinal flexion,
extension and lateral
flexion cause
compression on one
side and tension on
the other side of disc.

Rotations create shear
stress
Intervertebral disc

Disc has blood supply up to the age of 8 years.

Relies on mechanically based means for maintaining a
healthy nutritional status.

Changes in posture alter disc pressure causing a
pumping action.
Think

Why is it important not to maintain anyone body
position for too long?
Ligaments of the Spine

Anterior longitudinal ligament

Posterior longitudinal ligament

Supraspinous ligament (ligamentum nuchae in neck)

Interspinous

Intertransverse

Ligamntum flavum
Ligaments of spine

Enlarged cervical
portion of supraspinous
ligament is called
ligamentum nuchae or
ligament of neck.
Importance of ligamentum flavum

Contains high proportion of elastic fibers
which lengthen during spinal flexion and
shorten during extension.

Ligamentum flavum is in tension even when
spine is in anatomical position, enhancing
stability.

This creates constant compression in the discs
called prestress
Structure of the Spine
What are the primary spinal curves?

Thoracic and sacral curves

Concave anteriorly

Are present at birth
Structure of the Spine
What are the secondary spinal curves?

The lumbar and cervical curves

Concave posteriorly

Develop from supporting the body in an
upright position after young children
begin to sit and stand
Structure of the Spine
Summary

Vertebras

Facet joints

Intervertebral disc biomechanics

Ligaments of spine

Curves of spine