Biomechanics of the Cruciate Ligaments 15(A)(B)Figure 2.2 Longitudinal section of intact cranial
cruciate ligament (CrCL) from a 1.5-year-old female
beagle viewed using bright light (A) and circularly
polarized light (B). Intact CrCL from young dogs has a
hierarchically organized structure. Birefringence of the
extracellular matrix collagen and the crimped structure
are clearly visible in polarized light as bright and dark
repeating bands within ligament fibers. Crimp is a
wave-like feature of ligament that exists at the level of the
fiber, and is the primary reason for ligament’s nonlinear
elasticity. Scale bar= 50 μm.
loading in any off-axis direction and/or with
some stifle flexion would result in different stiff-
ness and strength.
All ligaments are viscoelastic in their mechan-
ical behavior. That is, their stretch will increase
during sustained loads (creep), and tensile
load required to maintain a fixed position will
decrease with time (relaxation). While impor-
tant, these biomechanical characteristics are
often considered secondary. Consequently, test-
ing protocols ‘pre-condition’ specimens with
repeated loads and testing at a constant rate of
loading to minimize secondary effects, produc-
ing a standard force versus deformation curve
that can be used for biomechanical comparison.Force–deformation curve
Structural properties are described using a
force–deformation curve, which can be divided
into three regions (Figure 2.3). The first is the
toe region, which is nonlinear and has a low ini-
tial stiffness; in this region, due to the crimped
nature of collagen fibers, small forces result in
a relatively large degree of lengthening. The
next region is the linear region, which displaysUltimate StrengthUltimate Elongation
Linear Slope700600
500400300
20010005 1 0
Deformation (mm)Force (N)15Energy-to-failureFigure 2.3 Typical force–deformation curve for
ligament during uniaxial tensile testing. The
force–deformation curve of ligament can be divided into
three regions. The toe region is the initial nonlinear part
of the curve, which is primarily due to the existence of
crimp at the level of the fiber. In this region, small forces
result in a large degree of lengthening because of the
crimped nature of the collagen fibers. The second is the
linear region, which occurs after crimp has been
maximally stretched. The linear slope of this region is
reflective of the material’s stiffness. The final region is the
point at which a ligament begins to rupture; the peak of
this part of the curve gives the material’s ultimate strength
and ultimate elongation values.