STUDY DESIGN: A biomechanical in vitro study on porcine and human spinal segments. OBJECTIVE: To investigate axial rotational stability of the thoracic spine under dorsal and ventral shear loads. SUMMARY OF BACKGROUND DATA: Idiopathic scoliosis is a condition restricted exclusively to humans. An important difference between humans and other vertebrates is the fact that humans ambulate in a fully erect position. It has been demonstrated that certain parts of the human spine, more specifically the dorsally inclined lower thoracic and high lumbar parts, are subject to dorsally directed shear loads. It has been hypothesized that these dorsal shear loads reduce the rotational stability of the spine, thereby increasing the risk to initiate idiopathic scoliosis. METHODS: Fourteen porcine and 14 human thoracic functional spinal units (FSUs) with intact costotransverse and costovertebral articulations were used for biomechanical testing. In both dorsal and ventral directions, shear loads were applied to the upper vertebra of the FSU in the midsagittal plane (centrally), and at 1 cm to the right and to the left (eccentrically), resulting in a rotary moment. Vertebral rotation was measured at 3 incremental loads by an automated optoelectronic 3-dimensional (3D) movement registration system. RESULTS: The results of this study showed that eccentrically applied shear loads induce vertebral rotation in human as well as in porcine spinal segments. At the mid-thoracic and lower thoracic levels, significantly more vertebral rotation occurred under dorsal shear loads than under ventral shear loads. CONCLUSION: These data show that, in humans and in quadrupeds, the thoracic spine is less rotationally stable under dorsal shear loads than under ventral shear loads.
STUDY DESIGN: A biomechanical in vitro study on porcine and human spinal segments. OBJECTIVE: To investigate axial rotational stability of the thoracic spine under dorsal and ventral shear loads. SUMMARY OF BACKGROUND DATA: Idiopathic scoliosis is a condition restricted exclusively to humans. An important difference between humans and other vertebrates is the fact that humans ambulate in a fully erect position. It has been demonstrated that certain parts of the human spine, more specifically the dorsally inclined lower thoracic and high lumbar parts, are subject to dorsally directed shear loads. It has been hypothesized that these dorsal shear loads reduce the rotational stability of the spine, thereby increasing the risk to initiate idiopathic scoliosis. METHODS: Fourteen porcine and 14 human thoracic functional spinal units (FSUs) with intact costotransverse and costovertebral articulations were used for biomechanical testing. In both dorsal and ventral directions, shear loads were applied to the upper vertebra of the FSU in the midsagittal plane (centrally), and at 1 cm to the right and to the left (eccentrically), resulting in a rotary moment. Vertebral rotation was measured at 3 incremental loads by an automated optoelectronic 3-dimensional (3D) movement registration system. RESULTS: The results of this study showed that eccentrically applied shear loads induce vertebral rotation in human as well as in porcine spinal segments. At the mid-thoracic and lower thoracic levels, significantly more vertebral rotation occurred under dorsal shear loads than under ventral shear loads. CONCLUSION: These data show that, in humans and in quadrupeds, the thoracic spine is less rotationally stable under dorsal shear loads than under ventral shear loads.
Authors: Rob C Brink; Ludvig Vavruch; Tom P C Schlösser; Kasim Abul-Kasim; Acke Ohlin; Hans Tropp; René M Castelein; Tomaž Vrtovec Journal: Eur Spine J Date: 2018-08-20 Impact factor: 3.134
Authors: Michiel M A Janssen; Koen L Vincken; Bastiaan Kemp; Marina Obradov; Marinus de Kleuver; Max A Viergever; René M Castelein; Lambertus W Bartels Journal: Eur Spine J Date: 2010-04-20 Impact factor: 3.134
Authors: Theodoros B Grivas; R Geoffrey Burwell; Constantinos Mihas; Elias S Vasiliadis; Georgios Triantafyllopoulos; Angelos Kaspiris Journal: Scoliosis Date: 2009-06-30
Authors: Jelle F Homans; Steven de Reuver; Tracy Heung; Candice K Silversides; Erwin N Oechslin; Michiel L Houben; Donna M McDonald-McGinn; Moyo C Kruyt; René M Castelein; Anne S Bassett Journal: Spine J Date: 2020-01-18 Impact factor: 4.166