Tunneling Schmorl's nodes

Abstract Background and importance: Butterfly vertebra is an uncommon congenital spinal anomaly, which can be easily mistaken for vertebral fracture, infection or tumor. Clinical presentation: We report the case of a 20-year-old male patient with a 3-year history of intermittent mid-thoracic spinal pain. Local examination showed a mild thoracic kyphoscoliosis. Neurological examination was normal. Computer tomography revealed the presence of a T6 butterfly vertebra associated with morphological anomalies in adjacent vertebral bodies and T6-T9 Schmorl’s nodes. MRI scan confirmed the diagnosis and additionally showed a mild spinal stenosis caused by apparent posterior epidural fat hypertrophy. The patient was treated with painkillers and physical therapy. Conclusion: Butterfly vertebra is a benign condition. Once diagnosed, additional diagnostic procedures are not necessary. Neurosurgeons must be aware of this congenital anomaly that should not be confused with a vertebral fracture.

Download Full-text

Schmorl’s nodes: demystification road of endplate defects—a critical review

Spine Deformity ◽

10.1007/s43390-021-00445-w ◽

2021 ◽

Author(s):

Hamida Azzouzi ◽

Linda Ichchou

Keyword(s):

Critical Review ◽

Schmorl’S Nodes

Download Full-text

Spondylolysis and spinal adaptations for bipedalism

Evolution Medicine and Public Health ◽

10.1093/emph/eoaa003 ◽

2020 ◽

Vol 2020 (1) ◽

pp. 35-44

Author(s):

Kimberly A Plomp ◽

Keith Dobney ◽

Mark Collard

Keyword(s):

Fatigue Fracture ◽

Evolutionary History ◽

Homo Sapiens ◽

Lumbar Vertebrae ◽

Great Ape ◽

Shape Variation ◽

3D Data ◽

Schmorl’S Nodes ◽

Vertebral Shape ◽

Range Of Variation

Abstract Background and objectives The study reported here focused on the aetiology of spondylolysis, a vertebral pathology usually caused by a fatigue fracture. The goal was to test the Overshoot Hypothesis, which proposes that people develop spondylolysis because their vertebral shape is at the highly derived end of the range of variation within Homo sapiens. Methodology We recorded 3D data on the final lumbar vertebrae of H. sapiens and three great ape species, and performed three analyses. First, we compared H. sapiens vertebrae with and without spondylolysis. Second, we compared H. sapiens vertebrae with and without spondylolysis to great ape vertebrae. Lastly, we compared H. sapiens vertebrae with and without spondylolysis to great ape vertebrae and to vertebrae of H. sapiens with Schmorl’s nodes, which previous studies have shown tend to be located at the ancestral end of the range of H. sapiens shape variation. Results We found that H. sapiens vertebrae with spondylolysis are significantly different in shape from healthy H. sapiens vertebrae. We also found that H. sapiens vertebrae with spondylolysis are more distant from great ape vertebrae than are healthy H. sapiens vertebrae. Lastly, we found that H. sapiens vertebrae with spondylolysis are at the opposite end of the range of shape variation than vertebrae with Schmorl’s nodes. Conclusions Our findings indicate that H. sapiens vertebrae with spondylolysis tend to exhibit highly derived traits and therefore support the Overshoot Hypothesis. Spondylolysis, it appears, is linked to our lineage’s evolutionary history, especially its shift from quadrupedalism to bipedalism. Lay summary: Spondylolysis is a relatively common vertebral pathology usually caused by a fatigue fracture. There is reason to think that it might be connected with our lineage’s evolutionary shift from walking on all fours to walking on two legs. We tested this idea by comparing human vertebrae with and without spondylolysis to the vertebrae of great apes. Our results support the hypothesis. They suggest that people who experience spondylolysis have vertebrae with what are effectively exaggerated adaptations for bipedalism.

Download Full-text