Your search keyword '"Zhicheng Liu"' showing total 11 results

1. Fluid and structure coupling analysis of the interaction between aqueous humor and iris

Author

Xiuqing Qian, Zhicheng Liu, Wenjia Wang, Hongfang Song, and Mindi Zhang

Subjects

Intraocular pressure, Materials science, genetic structures, Anterior Chamber, 0206 medical engineering, Finite Element Analysis, Biomedical Engineering, Glaucoma, Iris, 02 engineering and technology, Deformation (meteorology), Biomaterials, Aqueous Humor, 03 medical and health sciences, 0302 clinical medicine, Optics, Imaging, Three-Dimensional, Fluid–structure interaction, medicine, Fluid dynamics, Image Processing, Computer-Assisted, Humans, Radiology, Nuclear Medicine and imaging, Computer Simulation, Iris (anatomy), Intraocular Pressure, Radiological and Ultrasound Technology, business.industry, Models, Cardiovascular, Temperature, General Medicine, Mechanics, medicine.disease, 020601 biomedical engineering, eye diseases, medicine.anatomical_structure, Particle image velocimetry, Printing, Three-Dimensional, 030221 ophthalmology & optometry, Hydrodynamics, Human eye, sense organs, business, Software

Abstract

Glaucoma is the primary cause of irreversible blindness worldwide associated with high intraocular pressure (IOP). Elevated intraocular pressure will affect the normal aqueous humor outflow, resulting in deformation of iris. However, the deformation ability of iris is closely related to its material properties. Meanwhile, the passive deformation of the iris aggravates the pupillary block and angle closure. The nature of the interaction mechanism of iris deformation and aqueous humor fluid flow has not been fully understood and has been somewhat a controversial issue. The purpose here was to study the effect of IOP, localization, and temperature on the flow of the aqueous humor and the deformation of iris interacted by aqueous humor fluid flow. Based on mechanisms of aqueous physiology and fluid dynamics, 3D model of anterior chamber (AC) was constructed with the human anatomical parameters as a reference. A 3D idealized standard geometry of anterior segment of human eye was performed. Enlarge the size of the idealization geometry model 5 times to create a simulation device by using 3D printing technology. In this paper, particle image velocimetry technology is applied to measure the characteristic of fluid outflow in different inlet velocity based on the device. Numerically calculations were made by using ANSYS 14.0 Finite Element Analysis. Compare of the velocity distributions to confirm the validity of the model. The fluid structure interaction (FSI) analysis was carried out in the valid geometry model to study the aqueous flow and iris change. In this paper, the validity of the model is verified through computation and comparison. The results indicated that changes of gravity direction of model significantly affected the fluid dynamics parameters and the temperature distribution in anterior chamber. Increased pressure and the vertical position increase the velocity of the aqueous humor fluid flow, with the value increased of 0.015 and 0.035 mm/s. The results act on the iris showed that, gravity direction from horizontal to vertical decrease the equivalent stress in the normal IOP model, while almost invariably in the high IOP model. With the increased of the iris elasticity modulus, the equivalent strain and the total deformation of iris is decreased. The maximal value of equivalent strain of iris in high IOP model is higher than that of in normal IOP model. The maximum deformation of iris is lower in the high IOP model than in the normal IOP model. The valid model of idealization geometry of human eye could be helpful to study the relationship between localization, iris deformation and IOP. So far the FSI analysis was carried out in that idealization geometry model of anterior segment to study aqueous flow and iris change.

Published

2017

2. Microstructure visualization of conventional outflow pathway and finite element modeling analysis of trabecular meshwork

Author

Wei Zheng, Zhicheng Liu, Xi Mei, Qiang Xu, Lin Ren, and Jing Zhang

Subjects

Intraocular pressure, Materials science, genetic structures, Finite Element Analysis, Biomedical Engineering, Ocular hypertension, Glaucoma, 01 natural sciences, 010309 optics, Biomaterials, Aqueous Humor, 03 medical and health sciences, Tonometry, Ocular, 0302 clinical medicine, Imaging, Three-Dimensional, Trabecular Meshwork, 0103 physical sciences, medicine, Image Processing, Computer-Assisted, Animals, Humans, Radiology, Nuclear Medicine and imaging, Computer Simulation, 3D reconstruction, Finite element modeling, Intraocular Pressure, Aqueous solution, Radiological and Ultrasound Technology, Research, Microcirculation, Models, Cardiovascular, Conventional outflow pathway, General Medicine, Trans-scleral imaging method, medicine.disease, Microstructure, Finite element method, eye diseases, Rats, medicine.anatomical_structure, 030221 ophthalmology & optometry, Outflow, Trabecular meshwork, sense organs, Porosity, Sclera, Biomedical engineering

Abstract

Background The intraocular pressure (IOP) is maintained through a dynamic equilibrium between the production and drainage of aqueous humor. Elevation of intraocular pressure is mainly caused by the blocking of aqueous humor outflow pathway. Therefore, it is particularly important to study the structure of drainage pathway and the effect of ocular hypertension at the process of aqueous humor outflow. Methods Conventional drainage pathway of aqueous humor, including trabecular meshwork (TM), Schlemm’s canal (SC) and aqueous vein, were imaged by using trans-scleral imaging method with lateral resolution of 2 μm. For quantitative assessment, the morphological parameters of the TM were measured with different IOP levels via a combination of measurements and simulations. Results Images of the TM and the adjacent tissues were obtained. The porosity of TM with normal intraocular pressure varies from 0.63 to 0.74 as the depth increases, while in high IOP it is changed from 0.44 to 0.59. The diameter of aqueous vein varies from 32 to 43 μm, and is smaller than that of SC, which varies from 48 to 64.67 μm. Conclusions Our research provides a non-contact method to visualize the microstructure of tissue for clinical examination associated with the blocking of the outflow pathway of aqueous humor in humans. The three-dimensional (3D) microstructures of limbus and the results of finite element modeling analysis of the TM model will serve for the future evaluation of new glaucoma surgical techniques.

Published

2016

3. Experimental research on intraocular aqueous flow by PIV method

Author

Xi Mei, Xineng Fu, Hongyu Yang, Lin Li, Hongfang Song, Zhicheng Liu, and Mindi Zhang

Subjects

Intraocular pressure, Time Factors, Materials science, genetic structures, Aqueous humor flow, Intraocular aqueous flow, Biomedical Engineering, Aqueous humor, Velocity vector, Aqueous Humor, Biomaterials, Optics, Animals, Radiology, Nuclear Medicine and imaging, Radiological and Ultrasound Technology, business.industry, Research, General Medicine, Flow field, eye diseases, Experimental research, PIV, Hydrodynamics, Rabbits, sense organs, Rheology, business, Biomedical engineering

Abstract

Background Aqueous humor flows regularly from posterior chamber to anterior chamber, and this flow much involves intraocular pressure, the eye tissue nutrition and metabolism. Purpose To visualize and measure the intraocular flow regular pattern of aqueous humor. Method Intraocular flow in the vitro eyeball is driven to simulate the physiological aqueous humor flow, and the flow field is measured by Particle Image Velocimetry(PIV). Fluorescent particle solution of a certain concentration was infused into the root of Posterior Chamber(PC) of vitro rabbit eye to simulate the generation of aqueous and was drained out at a certain hydrostatic pressure from the angle of Anterior Chamber(AC) to represent the drainage of aqueous. PIV method was used to record and calculate the flow on the midsagittal plane of the eyeball. Results Velocity vector distribution in AC has been obtained, and the distribution shows symmetry feature to some extent. Fluorescent particle solution first fills the PC as it is continuously infused, then surges into AC through the pupil, flows upwards toward the central cornea, reflecting and scattering, and eventually converges along the inner cornea surface towards the outflow points at the periphery of the eyeball. Velocity values around the pupillary margin are within the range of 0.008-0.012 m/s, which are close to theoretical values of 0.0133 m/s, under the driving rate of 100 μl/min. Conclusions Flow field of aqueous humor can be measured by PIV method, which makes it possible to study the aqueous humor dynamics by experimental method. Our study provides a basis for experimental research on aqueous humor flow; further, it possibly helps to diagnose and treat eye diseases as shear force damage of ocular tissues and destructions on corneal endothelial cells from the point of intraocular flow field.

Published

2013

4. Three-dimensional reconstruction of blood vessels in the rabbit eye by X-ray phase contrast imaging

Author

Kunya Zhang, Xiuqing Qian, Zhicheng Liu, Qianqian Cui, Qiuyun Zhao, and Lu Zhang

Subjects

Long posterior ciliary arteries, Biomedical Engineering, Glaucoma, Three-dimensional reconstruction, Fundus (eye), Eye, Biomaterials, Imaging, Three-Dimensional, Vessel density, Blood vessels, medicine.artery, Animals, Medicine, Radiology, Nuclear Medicine and imaging, Radiological and Ultrasound Technology, business.industry, Research, Angiography, Rabbit (nuclear engineering), General Medicine, medicine.disease, X-ray phase-contrast imaging, medicine.anatomical_structure, Density distribution, X-Ray Phase-Contrast Imaging, Rabbits, business, Artery, Biomedical engineering

Abstract

Background A clear understanding of the blood vessels in the eye is helpful in the diagnosis and treatment of ophthalmic diseases, such as glaucoma. Conventional techniques such as micro-CT imaging and histology are not sufficiently accurate to identify the vessels in the eye, because their diameter is just a few microns. The newly developed medical imaging technology, X-ray phase-contrast imaging (XPCI), is able to distinguish the structure of the vessels in the eye. In this study, XPCI was used to identify the internal structure of the blood vessels in the eye. Methods After injection with barium sulfate via the ear border artery, an anesthetized rabbit was killed and its eye was fixed in vitro in 10% formalin solution. We acquired images using XPCI at the Shanghai Synchrotron Radiation Facility. The datasets were converted into slices by filtered back-projection (FBP). An angiographic score was obtained as a parameter to quantify the density of the blood vessels. A three-dimensional (3D) model of the blood vessels was then established using Amira 5.2 software. Results With XPCI, blood vessels in the rabbit eye as small as 18 μm in diameter and a sixth of the long posterior ciliary artery could be clearly distinguished. In the 3D model, we obtained the level 4 branch structure of vessels in the fundus. The diameters of the arteria centralis retinae and its branches are about 200 μm, 110 μm, 95 μm, 80 μm and 40 μm. The diameters of the circulus arteriosus iridis major and its branches are about 210 μm, 70 μm and 30 μm. Analysis of vessel density using the angiographic score showed that the blood vessels had maximum density in the fundus and minimum density in the area anterior to the equator (scores 0.27 ± 0.029 and 0.16 ± 0.032, respectively). We performed quantitative angiographic analysis of the blood vessels to further investigate the density of the vessels. Conclusions XPCI provided a feasible means to determine the structure of the blood vessels in the eye. We were able to determine the diameters and morphological characteristics of the vessels from both 2D images and the 3D model. By analyzing the images, we obtained measurements of the density distribution of the microvasculature, and this approach may provide valuable reference information prior to glaucoma filtration surgery.

Published

2013

5. Microstructure visualization of conventional outflow pathway and finite element modeling analysis of trabecular meshwork.

Author

Jing Zhang, Lin Ren, Xi Mei, Qiang Xu, Wei Zheng, Zhicheng Liu, Zhang, Jing, Ren, Lin, Mei, Xi, Xu, Qiang, Zheng, Wei, and Liu, Zhicheng

Subjects

TRABECULAR meshwork (Eye), FINITE element method, MICROSTRUCTURE, INTRAOCULAR pressure, AQUEOUS humor, MATHEMATICAL models, ANTERIOR eye segment, ANIMALS, BIOLOGICAL models, COMPUTER simulation, GLAUCOMA, DIGITAL image processing, MICROCIRCULATION, PHYSICS, RATS, SCLERA, TONOMETRY, THREE-dimensional imaging, PHYSIOLOGY

Abstract

Background: The intraocular pressure (IOP) is maintained through a dynamic equilibrium between the production and drainage of aqueous humor. Elevation of intraocular pressure is mainly caused by the blocking of aqueous humor outflow pathway. Therefore, it is particularly important to study the structure of drainage pathway and the effect of ocular hypertension at the process of aqueous humor outflow.Methods: Conventional drainage pathway of aqueous humor, including trabecular meshwork (TM), Schlemm's canal (SC) and aqueous vein, were imaged by using trans-scleral imaging method with lateral resolution of 2 μm. For quantitative assessment, the morphological parameters of the TM were measured with different IOP levels via a combination of measurements and simulations.Results: Images of the TM and the adjacent tissues were obtained. The porosity of TM with normal intraocular pressure varies from 0.63 to 0.74 as the depth increases, while in high IOP it is changed from 0.44 to 0.59. The diameter of aqueous vein varies from 32 to 43 μm, and is smaller than that of SC, which varies from 48 to 64.67 μm.Conclusions: Our research provides a non-contact method to visualize the microstructure of tissue for clinical examination associated with the blocking of the outflow pathway of aqueous humor in humans. The three-dimensional (3D) microstructures of limbus and the results of finite element modeling analysis of the TM model will serve for the future evaluation of new glaucoma surgical techniques. [ABSTRACT FROM AUTHOR]

Published

2016

6. An inverse method to determine the mechanical properties of the iris in vivo

Author

Xiuqing Qian, Kunya Zhang, Zhicheng Liu, and Xi Mei

Subjects

Finite element method, Materials science, Finite Element Analysis, Biomedical Engineering, Iris, In vivo experiment, urologic and male genital diseases, Displacement (vector), Biomaterials, In vivo, medicine, Image Processing, Computer-Assisted, Animals, Radiology, Nuclear Medicine and imaging, Sensitivity (control systems), Iris (anatomy), Mechanical Phenomena, Radiological and Ultrasound Technology, Multi-island genetic algorithm, urogenital system, Research, fungi, General Medicine, Biomechanical Phenomena, Molecular Imaging, medicine.anatomical_structure, Ultrasonic sensor, Rabbits, Material properties, Biomedical engineering

Abstract

Background Understanding the mechanical properties of the iris can help to have an insight into the eye diseases with abnormalities of the iris morphology. Material parameters of the iris were simply calculated relying on the ex vivo experiment. However, the mechanical response of the iris in vivo is different from that ex vivo, therefore, a method was put forward to determine the material parameters of the iris using the optimization method in combination with the finite element method based on the in vivo experiment. Material and methods Ocular hypertension was induced by rapid perfusion to the anterior chamber, during perfusion intraocular pressures in the anterior and posterior chamber were record by sensors, images of the anterior segment were captured by the ultrasonic system. The displacement of the characteristic points on the surface of the iris was calculated. A finite element model of the anterior chamber was developed using the ultrasonic image before perfusion, the multi-island genetic algorithm was employed to determine the material parameters of the iris by minimizing the difference between the finite element simulation and the experimental measurements. Results Material parameters of the iris in vivo were identified as the iris was taken as a nearly incompressible second-order Ogden solid. Values of the parameters μ1, α1, μ2 and α2 were 0.0861 ± 0.0080 MPa, 54.2546 ± 12.7180, 0.0754 ± 0.0200 MPa, and 48.0716 ± 15.7796 respectively. The stability of the inverse finite element method was verified, the sensitivity of the model parameters was investigated. Conclusion Material properties of the iris in vivo could be determined using the multi-island genetic algorithm coupled with the finite element method based on the experiment.

Published

2014

7. An inverse method to determine the mechanical properties of the iris in vivo.

Author

Kunya Zhang, Xiuqing Qian, Xi Mei, and Zhicheng Liu

Subjects

IRIS (Eye), EYE diseases, ULTRASONIC imaging, FINITE element method, GENETIC algorithms, PERFUSION

Abstract

Background Understanding the mechanical properties of the iris can help to have an insight into the eye diseases with abnormalities of the iris morphology. Material parameters of the iris were simply calculated relying on the ex vivo experiment. However, the mechanical response of the iris in vivo is different from that ex vivo, therefore, a method was put forward to determine the material parameters of the iris using the optimization method in combination with the finite element method based on the in vivo experiment. Material and methods Ocular hypertension was induced by rapid perfusion to the anterior chamber, during perfusion intraocular pressures in the anterior and posterior chamber were record by sensors, images of the anterior segment were captured by the ultrasonic system. The displacement of the characteristic points on the surface of the iris was calculated. A finite element model of the anterior chamber was developed using the ultrasonic image before perfusion, the multiisland genetic algorithm was employed to determine the material parameters of the iris by minimizing the difference between the finite element simulation and the experimental measurements. Results Material parameters of the iris in vivo were identified as the iris was taken as a nearly incompressible second-order Ogden solid. Values of the parameters μ1, α1, μ2 and α2 were 0.0861 ± 0.0080 MPa, 54.2546 ± 12.7180, 0.0754 ± 0.0200 MPa, and 48.0716 ± 15.7796 respectively. The stability of the inverse finite element method was verified, the sensitivity of the model parameters was investigated. Conclusion Material properties of the iris in vivo could be determined using the multi-island genetic algorithm coupled with the finite element method based on the experiment. [ABSTRACT FROM AUTHOR]

Published

2014

8. Experimental research on intraocular aqueous flow by PIV method.

Author

Hongyu Yang, Hongfang Song, Xi Mei, Lin Li, Xineng Fu, Mindi Zhang, and Zhicheng Liu

Subjects

PARTICLE image velocimetry, AQUEOUS humor, INTRAOCULAR pressure, HYDROSTATIC pressure, EYE diseases

Abstract

Background Aqueous humor flows regularly from posterior chamber to anterior chamber, and this flow much involves intraocular pressure, the eye tissue nutrition and metabolism. Purpose To visualize and measure the intraocular flow regular pattern of aqueous humor. Method Intraocular flow in the vitro eyeball is driven to simulate the physiological aqueous humor flow, and the flow field is measured by Particle Image Velocimetry(PIV). Fluorescent particle solution of a certain concentration was infused into the root of Posterior Chamber(PC) of vitro rabbit eye to simulate the generation of aqueous and was drained out at a certain hydrostatic pressure from the angle of Anterior Chamber(AC) to represent the drainage of aqueous. PIV method was used to record and calculate the flow on the midsagittal plane of the eyeball. Results Velocity vector distribution in AC has been obtained, and the distribution shows symmetry feature to some extent. Fluorescent particle solution first fills the PC as it is continuously infused, then surges into AC through the pupil, flows upwards toward the central cornea, reflecting and scattering, and eventually converges along the inner cornea surface towards the outflow points at the periphery of the eyeball. Velocity values around the pupillary margin are within the range of 0.008-0.012 m/s, which are close to theoretical values of 0.0133 m/s, under the driving rate of 100 μl/min. Conclusions Flow field of aqueous humor can be measured by PIV method, which makes it possible to study the aqueous humor dynamics by experimental method. Our study provides a basis for experimental research on aqueous humor flow; further, it possibly helps to diagnose and treat eye diseases as shear force damage of ocular tissues and destructions on corneal endothelial cells from the point of intraocular flow field. [ABSTRACT FROM AUTHOR]

Published

2013

9. Three-dimensional reconstruction of blood vessels in the rabbit eye by X-ray phase contrast imaging.

Author

Lu Zhang, Xiuqing Qian, Kunya Zhang, Qianqian Cui, Qiuyun Zhao, and Zhicheng Liu

Subjects

BLOOD vessels, RABBITS, DIAGNOSIS of eye diseases, GLAUCOMA diagnosis, DIAGNOSTIC imaging, HISTOPATHOLOGY

Abstract

Background: A clear understanding of the blood vessels in the eye is helpful in the diagnosis and treatment of ophthalmic diseases, such as glaucoma. Conventional techniques such as micro-CT imaging and histology are not sufficiently accurate to identify the vessels in the eye, because their diameter is just a few microns. The newly developed medical imaging technology, X-ray phase-contrast imaging (XPCI), is able to distinguish the structure of the vessels in the eye. In this study, XPCI was used to identify the internal structure of the blood vessels in the eye. Methods: After injection with barium sulfate via the ear border artery, an anesthetized rabbit was killed and its eye was fixed in vitro in 10% formalin solution. We acquired images using XPCI at the Shanghai Synchrotron Radiation Facility. The datasets were converted into slices by filtered back-projection (FBP). An angiographic score was obtained as a parameter to quantify the density of the blood vessels. A three-dimensional (3D) model of the blood vessels was then established using Amira 5.2 software. Results: With XPCI, blood vessels in the rabbit eye as small as 18 μm in diameter and a sixth of the long posterior ciliary artery could be clearly distinguished. In the 3D model, we obtained the level 4 branch structure of vessels in the fundus. The diameters of the arteria centralis retinae and its branches are about 200 μm, 110 μm, 95 μm, 80 μm and 40 μm. The diameters of the circulus arteriosus iridis major and its branches are about 210 μm, 70 μm and 30 μm. Analysis of vessel density using the angiographic score showed that the blood vessels had maximum density in the fundus and minimum density in the area anterior to the equator (scores 0.27 ± 0.029 and 0.16 ± 0.032, respectively). We performed quantitative angiographic analysis of the blood vessels to further investigate the density of the vessels. Conclusions: XPCI provided a feasible means to determine the structure of the blood vessels in the eye. We were able to determine the diameters and morphological characteristics of the vessels from both 2D images and the 3D model. By analyzing the images, we obtained measurements of the density distribution of the microvasculature, and this approach may provide valuable reference information prior to glaucoma filtration surgery. [ABSTRACT FROM AUTHOR]

Published

2013

10. Erratum to: Fluid and structure coupling analysis of the interaction between aqueous humor and iris

Author

Xiuqing Qian, Wenjia Wang, Zhicheng Liu, Mindi Zhang, and Hongfang Song

Subjects

genetic structures, Intraocular pressure, 0206 medical engineering, Biomedical Engineering, Mechanical properties, Aqueous humor, 02 engineering and technology, Biomaterials, medicine, Radiology, Nuclear Medicine and imaging, Iris deformation, Iris (anatomy), Radiological and Ultrasound Technology, Chemistry, Research, General Medicine, 020601 biomedical engineering, eye diseases, Coupling (electronics), medicine.anatomical_structure, Chemical physics, sense organs, Erratum, Fluid–structure interaction, Biomedical engineering

Abstract

Background Glaucoma is the primary cause of irreversible blindness worldwide associated with high intraocular pressure (IOP). Elevated intraocular pressure will affect the normal aqueous humor outflow, resulting in deformation of iris. However, the deformation ability of iris is closely related to its material properties. Meanwhile, the passive deformation of the iris aggravates the pupillary block and angle closure. The nature of the interaction mechanism of iris deformation and aqueous humor fluid flow has not been fully understood and has been somewhat a controversial issue. The purpose here was to study the effect of IOP, localization, and temperature on the flow of the aqueous humor and the deformation of iris interacted by aqueous humor fluid flow. Methods Based on mechanisms of aqueous physiology and fluid dynamics, 3D model of anterior chamber (AC) was constructed with the human anatomical parameters as a reference. A 3D idealized standard geometry of anterior segment of human eye was performed. Enlarge the size of the idealization geometry model 5 times to create a simulation device by using 3D printing technology. In this paper, particle image velocimetry technology is applied to measure the characteristic of fluid outflow in different inlet velocity based on the device. Numerically calculations were made by using ANSYS 14.0 Finite Element Analysis. Compare of the velocity distributions to confirm the validity of the model. The fluid structure interaction (FSI) analysis was carried out in the valid geometry model to study the aqueous flow and iris change. Results In this paper, the validity of the model is verified through computation and comparison. The results indicated that changes of gravity direction of model significantly affected the fluid dynamics parameters and the temperature distribution in anterior chamber. Increased pressure and the vertical position increase the velocity of the aqueous humor fluid flow, with the value increased of 0.015 and 0.035 mm/s. The results act on the iris showed that, gravity direction from horizontal to vertical decrease the equivalent stress in the normal IOP model, while almost invariably in the high IOP model. With the increased of the iris elasticity modulus, the equivalent strain and the total deformation of iris is decreased. The maximal value of equivalent strain of iris in high IOP model is higher than that of in normal IOP model. The maximum deformation of iris is lower in the high IOP model than in the normal IOP model. Conclusion The valid model of idealization geometry of human eye could be helpful to study the relationship between localization, iris deformation and IOP. So far the FSI analysis was carried out in that idealization geometry model of anterior segment to study aqueous flow and iris change.

11. Compression-distraction reduction surgical verification and optimization to treat the basilar invagination and atlantoaxial dislocation: a finite element analysis

Author

Xuefeng Bo, Weida Wang, Zhicheng Liu, and Zan Chen

Subjects

Surgical optimization, medicine.medical_specialty, Compressive Strength, Medullary cavity, medicine.medical_treatment, Finite Element Analysis, 0206 medical engineering, Joint Dislocations, Basilar invagination, Biomedical Engineering, 02 engineering and technology, Biomaterials, 03 medical and health sciences, Imaging, Three-Dimensional, 0302 clinical medicine, Spinal cord compression, medicine, Humans, Internal fixation, Computer Simulation, Radiology, Nuclear Medicine and imaging, Reduction (orthopedic surgery), Orthodontics, Compression-distraction reduction technique, Radiological and Ultrasound Technology, business.industry, Ossification, Research, Reproducibility of Results, Equipment Design, General Medicine, medicine.disease, Compression (physics), Atlantoaxial dislocation, 020601 biomedical engineering, Surgery, Spinal Fusion, medicine.anatomical_structure, Atlanto-Axial Joint, Cervical Vertebrae, medicine.symptom, Tomography, X-Ray Computed, business, Software, 030217 neurology & neurosurgery, Cervical vertebrae

Abstract

Background Basilar invagination (BI) combined with atlantoaxial dislocation (AAD) leads to foramen magnum stenosis and medullary spinal cord compression, causing nerve dysfunction. The purpose of the surgery is to remove the bony compression at brainstem ventral side and fix the unstable spinal segment and make it fused stably. Occipital cervical internal fixation system that simultaneously reduces atlantoaxial horizontal and vertical dislocation are established. We propose here a new compression-distraction reduction (CDR) technique. We aimed to construct a congenital BI-AAD preoperative finite element model (FEM) to simulate the CDR technique for AAD reduction surgery. Methods Based on computed tomographic scans of patients’ cervical vertebrae, a three-dimensional (3D) geometric model of the cervical spine (C0–C4) of congenital BI-AAD patients was established using Mimics13.1, Geomagic2012, and Space Claim14.0 softwares. The mechanical parameters of the tissues were assigned according to their material characteristics using ANSYS Workbench 14.0 software. A 3D FEM was established using the tetrahedral mesh method. The bending moment was loaded on C0. Physiological conditions—anteflexion, retroflexion, left and right flexion, left and right rotation—were simulated for preoperative verification. The occipital cervical fixation system FEM was established. The CDR technique was simulated to perform AAD reduction surgery. Data were obtained when the atlantoaxial horizontal and vertical dislocation reductions were verified postoperatively. Stress data for the two surgical schemes were analyzed, as was the reduction surgery optimization scheme for congenital BI-AAD patients with abnormal lateral atlantoaxial articulation ossification. Results Cervical spine (C0–C4) FEM of congenital BI-AAD patients was established. The CDR technique was simulated for AAD reduction. We obtained the mechanical data when the atlantoaxial horizontal and vertical dislocation reductions were satisfied for the two surgical schemes. Conclusions The CDR technique for AAD reduction was feasible and effective. We propose this reduction optimization scheme for patients with lateral atlantoaxial articulation due to abnormal ossification of congenital BI-AAD. We also provide a biomechanically theoretical basis for improving the reliability of pure posterior reduction surgery and simplifying surgery for complicated BI-AAD disease.