Your search keyword '"Ngoc Lam Nguyen"' showing total 3 results

1. Postural Consequences of Cervical Sagittal Imbalance

Author

Ngoc Lam Nguyen, Alexander J. Ghanayem, Avinash G. Patwardhan, Gerard Carandang, Zachary A. Smith, William R. Sears, Alpesh A. Patel, Robert M. Havey, Dale Schuit, Saeed Khayatzadeh, Leonard I. Voronov, and Muturi Muriuki

Subjects

Adult, Lordosis, Posture, Thoracic Vertebrae, Young Adult, Cadaver, Humans, Medicine, Orthopedics and Sports Medicine, Range of Motion, Articular, Orthodontics, business.industry, Biomechanics, Occiput, Anatomy, Middle Aged, medicine.disease, Sagittal plane, Biomechanical Phenomena, Vertebra, Radiography, medicine.anatomical_structure, Forward head posture, Cervical Vertebrae, Neurology (clinical), business, Range of motion, Head, Tilt (camera)

Abstract

Study design A biomechanical study using human spine specimens. Objective To study postural compensations in lordosis angles that are necessary to maintain horizontal gaze in the presence of forward head posture and increasing T1 sagittal tilt. Summary of background data Forward head posture relative to the shoulders, assessed radiographically using the horizontal offset distance between the C2 and C7 vertebral bodies (C2-C7 [sagittal vertical alignment] SVA), is a measure of global cervical imbalance. This may result from kyphotic alignment of cervical segments, muscle imbalance, as well as malalignment of thoracolumbar spine. Methods Ten cadaveric cervical spines (occiput-T1) were tested. The T1 vertebra was anchored to a tilting and translating base. The occiput was free to move vertically but its angular orientation was constrained to ensure horizontal gaze regardless of sagittal imbalance. A 5-kg mass was attached to the occiput to mimic head weight. Forward head posture magnitude and T1 tilt were varied and motions of individual vertebrae were measured to calculate C2-C7 SVA and lordosis across C0-C2 and C2-C7. Results Increasing C2-C7 SVA caused flexion of lower cervical (C2-C7) segments and hyperextension of suboccipital (C0-C1-C2) segments to maintain horizontal gaze. Increasing kyphotic T1 tilt primarily increased lordosis across the C2-C7 segments. Regression models were developed to predict the compensatory C0-C2 and C2-C7 angulation needed to maintain horizontal gaze given values of C2-C7 SVA and T1 tilt. Conclusion This study established predictive relationships between radiographical measures of forward head posture, T1 tilt, and postural compensations in the cervical lordosis angles needed to maintain horizontal gaze. The laboratory model predicted that normalization of C2-C7 SVA will reduce suboccipital (C0-C2) hyperextension, whereas T1 tilt reduction will reduce the hyperextension in the C2-C7 segments. The predictive relationships may help in planning corrective strategy in patients experiencing neck pain, which may be attributed to sagittal malalignment. Level of evidence N/A.

Published

2015

2. Is Cervical Sagittal Imbalance a Risk Factor for Adjacent Segment Pathomechanics After Multilevel Fusion?

Author

William R. Sears, Gerard Carandang, Alexander J. Ghanayem, Saeed Khayatzadeh, Laurie M Lomasney, Muturi Muriuki, Zachary A. Smith, Leonard I. Voronov, Avinash G. Patwardhan, Ngoc Lam Nguyen, and Robert M. Havey

Subjects

Adult, Male, medicine.medical_treatment, Radiography, Surgical planning, 03 medical and health sciences, Young Adult, 0302 clinical medicine, Risk Factors, medicine, Humans, Orthopedics and Sports Medicine, Range of Motion, Articular, Postural Balance, Aged, 030222 orthopedics, business.industry, Biomechanics, Anatomy, Middle Aged, Sagittal plane, Biomechanical Phenomena, medicine.anatomical_structure, Spinal Fusion, Spinal fusion, Cervical Vertebrae, Female, Neurology (clinical), business, Cadaveric spasm, Range of motion, 030217 neurology & neurosurgery, Cervical vertebrae

Abstract

STUDY DESIGN A biomechanical study using human spine specimens. OBJECTIVE The aim of this study was to assess whether the presence of cervical sagittal imbalance is an independent risk factor for increasing the mechanical burden on discs adjacent to cervical multilevel fusions. SUMMARY OF BACKGROUND DATA The horizontal offset distance between the C2 plumbline and C7 vertebral body (C2-C7 Sagittal Vertical Axis (SVA)) or the angle made with vertical by a line connecting the C2 and C7 vertebral bodies (C2-C7 tilt angle) are used as radiographic measures to assess cervical sagittal balance. There is level III clinical evidence that sagittal imbalance caused by kyphotic fusions or global spinal sagittal malalignment may increase the risk of adjacent segment pathology. METHODS Thirteen human cadaveric cervical spines (Occiput-T1; age: 50.6 years; range: 21-67) were tested first in the native intact state and then after instrumentation across C4-C6 to simulate in situ two-level fusion. Specimens were tested using a previously validated experimental model that allowed measurement of spinal response to prescribed imbalance. The effects of fusion on segmental angular alignments and intradiscal pressures in the C3-C4 and C6-C7 discs, above and below the fusion, were evaluated at different magnitudes of C2-C7 tilt angle (or C2-C7 SVA). RESULTS When compared with the pre-fusion state, in situ fusion across C4-C6 segments required increased flexion angulation and resulted in increased intradiscal pressure at the C6-C7 disc below the fusion in order to accommodate the same increase in C2-C7 tilt angle or C2-C7 SVA (P

Published

2015

3. Effect of physiological loads on cortical and traditional pedicle screw fixation

Author

Brett Lullo, Robert M. Havey, Gerard Carandang, Ngoc Lam Nguyen, Alexander J. Ghanayem, Daniel A. Baluch, Alpesh A. Patel, Leonard I. Voronov, and Avinash G. Patwardhan

Subjects

musculoskeletal diseases, Male, medicine.medical_specialty, Bone Screws, Statistical difference, Prosthesis Implantation, Weight-Bearing, Fixation (surgical), Lumbar, Cadaver, Medicine, Humans, Orthopedics and Sports Medicine, Quantitative computed tomography, Pedicle screw fixation, Pedicle screw, Orthodontics, medicine.diagnostic_test, business.industry, Middle Aged, musculoskeletal system, equipment and supplies, Spine, Surgery, Biomechanical Phenomena, Prosthesis Failure, surgical procedures, operative, Neurology (clinical), Stress, Mechanical, Cadaveric spasm, business, Tomography, X-Ray Computed

Abstract

Study design Human cadaveric biomechanical study. Objective To determine the fixation strength of laterally directed, cortical pedicle screws under physiological loads. Summary of background data Lateral trajectory cortical pedicle screws have been described as a means of obtaining improved fixation while minimizing soft-tissue dissection during lumbar instrumentation. Biomechanical data have demonstrated equivalent strength in a quasi-static model; however, no biomechanical information is available comparing the fixation of cortical with traditional pedicle screws under cyclic physiological loads. Methods Seventeen vertebral levels (T11-L5) underwent quantitative computed tomography. On 1 side, a laterally directed, cortical pedicle screw was inserted with a traditional, medially directed pedicle screw placed on the contralateral side. With the specimen constrained in a testing apparatus, each screw underwent cyclic craniocaudal toggling under incrementally increasing physiological loads until 2 mm of head displacement occurred. Next, uniaxial pullout of each toggled screw was performed. The number of craniocaudal toggle cycles and load (N) required to achieve pedicle screw movement as well as axial pullout resistance (N) were compared between the 2 techniques. Results The mean trabecular bone mineral density of the specimens was 202 K2HPO4 mg/cm. Cortical pedicle screws demonstrated significantly improved resistance to toggle testing, requiring 184 cycles to reach 2 mm of displacement compared with 102 cycles for the traditional pedicle screws (P=0.002). The force necessary to displace the screws was also significantly greater for the cortical versus the traditional screws (398 N vs. 300 N, P=0.004). There was no statistical difference in axial pullout strength between the previously toggled cortical and traditional pedicle screws (1722 N vs. 1741 N, P=0.837). Conclusion Laterally directed cortical pedicle screws have superior resistance to craniocaudal toggling compared with traditional pedicle screws. Level of evidence N/A.

Published

2014