3-D computational modelling of the human spine provides a sophisticated and
cost-effective medium for bioengineers, researchers, and ergonomics designers
in order to study the biomechanical behaviour of the human spine under different
loading conditions. Developing a generic parametric computational human spine
model to be employed in biomechanical modelling introduces a considerable
potential to reduce the complexity of implementing and amending the intricate
spinal geometry. The main objective of this research is to develop a 3-D
parametric human spine model generation framework based on a command file
system, by which the parameters of each vertebra are read from the database
system, and then modelled within commercial 3-D CAD software. A novel data
acquisition and generation system was developed as a part of the framework for
determining the unknown vertebral dimensions, depending on the correlations
between the parameters estimated from existing anthropometrical studies in the
literature. The data acquisition system embodies a predictive methodology that
comprehends the relations between the features of the vertebrae by employing
statistical and geometrical techniques. Relations amongst vertebral parameters
such as golden ratio were investigated and successfully implemented into the
algorithms. The validation of the framework was carried out by comparing the
developed 3-D computational human spine models against various real life
human spine data, where good agreements were achieved. The constructed
versatile framework possesses the capability to be utilised as a basis for quickly
and effectively developing biomechanical models of the human spine such as
finite element models.