Designs and techniques that improve the pullout strength of pedicle screws in osteoporotic vertebrae: current status.
Thomas M SheaJake LaunSabrina A Gonzalez-BlohmJames J DoulgerisWilliam E LeeKamran AghayevFrank D VrionisPublished in: BioMed research international (2014)
Osteoporosis is a medical condition affecting men and women of different age groups and populations. The compromised bone quality caused by this disease represents an important challenge when a surgical procedure (e.g., spinal fusion) is needed after failure of conservative treatments. Different pedicle screw designs and instrumentation techniques have been explored to enhance spinal device fixation in bone of compromised quality. These include alterations of screw thread design, optimization of pilot hole size for non-self-tapping screws, modification of the implant's trajectory, and bone cement augmentation. While the true benefits and limitations of any procedure may not be realized until they are observed in a clinical setting, axial pullout tests, due in large part to their reproducibility and ease of execution, are commonly used to estimate the device's effectiveness by quantifying the change in force required to remove the screw from the body. The objective of this investigation is to provide an overview of the different pedicle screw designs and the associated surgical techniques either currently utilized or proposed to improve pullout strength in osteoporotic patients. Mechanical comparisons as well as potential advantages and disadvantages of each consideration are provided herein.
Keyphrases
- bone mineral density
- postmenopausal women
- minimally invasive
- soft tissue
- body composition
- finite element analysis
- end stage renal disease
- current status
- spinal cord
- ejection fraction
- chronic kidney disease
- randomized controlled trial
- newly diagnosed
- healthcare
- bone loss
- prognostic factors
- bone regeneration
- study protocol
- quality improvement
- clinical trial
- patient reported outcomes
- single molecule
- robot assisted
- human health
- perovskite solar cells