A principal component analysis of the relationship between the external body shape and internal skeleton for the upper body.

Recent progress in 3D scanning technologies allows easy access to 3D human body envelope. To create personalized human models with an articulated linkage for realistic re-posturing and motion analyses, an accurate estimation of internal skeleton points, including joint centers, from the external envelope is required. For this research project, 3D reconstructions of both internal skeleton and external envelope from low dose biplanar X-rays of 40 male adults were obtained. Using principal component analysis technique (PCA), a low-dimensional dataset was used to predict internal points of the upper body from the trunk envelope. A least squares method was used to find PC scores that fit the PCA-based model to the envelope of a new subject. To validate the proposed approach, estimated internal points were evaluated using a leave-one-out (LOO) procedure, i.e. successively considering each individual from our dataset as an extra-subject. In addition, different methods were proposed to reduce the variability in data and improve the performance of the PCA-based prediction. The best method was considered as the one providing the smallest errors between estimated and reference internal points with an average error of 8.3mm anterior-posteriorly, 6.7mm laterally and 6.5mm vertically. As the proposed approach relies on few or no bony landmarks, it could be easily applicable and generalizable to surface scans from any devices. Combined with automatic body scanning techniques, this study could potentially constitute a new step towards automatic generation of external/internal subject-specific manikins.

[1]  Michael J. Black,et al.  Home 3D body scans from noisy image and range data , 2011, 2011 International Conference on Computer Vision.

[2]  Stephan Milosavljevic,et al.  Palpation identification of spinous processes in the lumbar spine. , 2007, Manual therapy.

[3]  P. Newton,et al.  Evaluation of a Functional Position for Lateral Radiograph Acquisition in Adolescent Idiopathic Scoliosis , 2004, Spine.

[4]  Wafa Skalli,et al.  Gravity Line Analysis in Adult Volunteers: Age-Related Correlation With Spinal Parameters, Pelvic Parameters, and Foot Position , 2006, Spine.

[5]  Matthew P. Reed,et al.  Rapid Generation of Custom Avatars using Depth Cameras , 2014 .

[6]  J. Hecquet,et al.  Pelvic incidence: a fundamental pelvic parameter for three-dimensional regulation of spinal sagittal curves , 1998, European Spine Journal.

[7]  P. Violas,et al.  The lumbar-pelvic-femoral complex: applications in spinal imbalance , 2010 .

[8]  S Laporte,et al.  Three-dimensional reconstruction of the lower limb from biplanar calibrated radiographs. , 2013, Medical engineering & physics.

[9]  D Mitton,et al.  3D reconstruction of the pelvis from bi-planar radiography , 2006, Computer methods in biomechanics and biomedical engineering.

[10]  Zoran Popovic,et al.  The space of human body shapes: reconstruction and parameterization from range scans , 2003, ACM Trans. Graph..

[11]  Wafa Skalli,et al.  3D reconstruction of rib cage geometry from biplanar radiographs using a statistical parametric model approach , 2016, Comput. methods Biomech. Biomed. Eng. Imaging Vis..

[12]  E. Berthonnaud,et al.  Sagittal morphology and equilibrium of pelvis and spine , 2002, European Spine Journal.

[13]  D B Chaffin,et al.  Improving digital human modelling for proactive ergonomics in design , 2005, Ergonomics.

[14]  A. Cappozzo,et al.  Pelvis and lower limb anatomical landmark calibration precision and its propagation to bone geometry and joint angles , 1999, Medical & Biological Engineering & Computing.

[15]  Matthew P Reed,et al.  Parametric body shape model of standing children aged 3–11 years , 2015, Ergonomics.

[16]  Matthew P. Reed,et al.  Methods for Measuring and Representing Automobile Occupant Posture , 1999 .

[17]  Farida Cheriet,et al.  Prediction of anterior scoliotic spinal curve from trunk surface using support vector regression , 2005, Eng. Appl. Artif. Intell..

[18]  Wafa Skalli,et al.  EOS: A NEW IMAGING SYSTEM WITH LOW DOSE RADIATION IN STANDING POSITION FOR SPINE AND BONE & JOINT DISORDERS , 2010 .

[19]  Micheline Gagnon,et al.  A Geometric Model of the Lumbar Spine in the Sagittal Plane , 1993, Spine.

[20]  Caterina Rizzi,et al.  The Role of Virtual Ergonomic Simulation to Develop Innovative Human Centered Products , 2015, HCI.

[21]  Sebastian Thrun,et al.  SCAPE: shape completion and animation of people , 2005, SIGGRAPH '05.

[22]  Patricia Dolan,et al.  Spine biomechanics. , 2005, Journal of biomechanics.

[23]  Matthew B. Parkinson,et al.  Developing and Implementing Parametric Human Body Shape Models in Ergonomics Software , 2014 .

[24]  Xuguang Wang,et al.  An assessment of the realism of digital human manikins used for simulation in ergonomics , 2015, Ergonomics.

[25]  Serge Van Sint Jan,et al.  Methods for determining hip and lumbosacral joint centers in a seated position from external anatomical landmarks. , 2015, Journal of biomechanics.

[26]  K. Han Kim,et al.  Statistical Prediction of Body Landmark Locations on Surface Scans , 2015 .

[27]  Matthew P Reed,et al.  Child body shape measurement using depth cameras and a statistical body shape model , 2015, Ergonomics.

[28]  T Huysmans,et al.  An active shape model for the reconstruction of scoliotic deformities from back shape data. , 2005, Clinical biomechanics.

[29]  Wafa Skalli,et al.  Radiographic analysis of the sagittal alignment and balance of the spine in asymptomatic subjects. , 2005, The Journal of bone and joint surgery. American volume.

[30]  M. Rousseau,et al.  Lumbar-pelvic-femoral balance on sitting and standing lateral radiographs. , 2013, Orthopaedics & traumatology, surgery & research : OTSR.

[31]  Richard A. Brand,et al.  Prediction of hip joint center location from external landmarks , 1987 .

[32]  M. Dijkers,et al.  Hip joint center location from palpable bony landmarks--a cadaver study. , 1995, Journal of biomechanics.

[33]  Peter Blanchonette,et al.  Jack Human Modelling Tool: A Review , 2010 .

[34]  B Drerup,et al.  Assessment of scoliotic deformity from back shape asymmetry using an improved mathematical model. , 1996, Clinical biomechanics.

[35]  H Parent,et al.  Applications in spinal imbalance. , 2010, Orthopaedics & traumatology, surgery & research : OTSR.

[36]  W Skalli,et al.  3D reconstruction of the spine from biplanar X-rays using parametric models based on transversal and longitudinal inferences. , 2009, Medical engineering & physics.

[37]  W Skalli,et al.  Fast 3D reconstruction of the lower limb using a parametric model and statistical inferences and clinical measurements calculation from biplanar X-rays , 2012, Computer methods in biomechanics and biomedical engineering.

[38]  Hélène Pillet,et al.  A 3D reconstruction method of the body envelope from biplanar X-rays: Evaluation of its accuracy and reliability. , 2015, Journal of biomechanics.

[39]  R. Brand,et al.  Prediction of hip joint centre location from external landmarks , 1989 .

[40]  Richard G. Snyder Link System of the Human Torso , 1972 .