Zachary A. Dooley scite author profile

This study investigates the biomechanical stability of a large interbody spacer inserted by a lateral approach and compares the biomechanical differences with the more conventional transforaminal interbody fusion (TLIF), with and without supplemental pedicle screw (PS) fixation. Twenty-four L2-L3 functional spinal units (FSUs) were tested with three interbody cage options: (i) 18 mm XLIF cage, (ii) 26 mm XLIF cage, and (iii) 11 mm TLIF cage. Each spacer was tested without supplemental fixation, and with unilateral and bilateral PS fixation. Specimens were subjected to multidirectional nondestructive flexibility tests to 7.5 N·m. The range of motion (ROM) differences were first examined within the same group (per cage) using repeated-measures ANOVA, and then compared between cage groups. The 26 mm XLIF cage provided greater stability than the 18 mm XLIF cage with unilateral PS and 11 mm TLIF cage with bilateral PS. The 18 mm XLIF cage with unilateral PS provided greater stability than the 11 mm TLIF cage with bilateral PS. This study suggests that wider lateral spacers are biomechanically stable and offer the option to be used with less or even no supplemental fixation for interbody lumbar fusion.

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Biomechanical Stability of Lateral Interbody Implants and Supplemental Fixation in a Cadaveric Degenerative Spondylolisthesis Model

Fogel¹,

Turner

Dooley

et al. 2014

Spine

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Femoral Nerve Strain at L4–L5 Is Minimized by Hip Flexion and Increased by Table Break When Performing Lateral Interbody Fusion

O’Brien

Haines

Dooley

et al. 2014

Spine

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Long Construct Pedicle Screw Reduction and Residual Forces are Decreased Using a Computer-Assisted Spinal Rod Bending System

et al. 2014

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Multiaxial spine testing apparatus: system characterisation by evaluation of analogue and cadaveric lumbar spines

Dooley

Turner

Corwall

2013

IJECB

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Zachary A. Dooley

Biomechanics of Lateral Interbody Spacers: Going Wider for Going Stiffer

Biomechanical Stability of Lateral Interbody Implants and Supplemental Fixation in a Cadaveric Degenerative Spondylolisthesis Model

Femoral Nerve Strain at L4–L5 Is Minimized by Hip Flexion and Increased by Table Break When Performing Lateral Interbody Fusion

Long Construct Pedicle Screw Reduction and Residual Forces are Decreased Using a Computer-Assisted Spinal Rod Bending System

Multiaxial spine testing apparatus: system characterisation by evaluation of analogue and cadaveric lumbar spines

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