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Spine near-end boundary angle operation optimization method based on finite elements and machine learning

A machine learning and optimization method technology, applied in the field of medical image processing, can solve problems such as low efficiency, cumbersome process, and optimization suggestions not given for specific orthopedic values ​​of spinal curvature, etc., and achieve the effect of reducing the occurrence of postoperative complications

Active Publication Date: 2020-09-04
WEST CHINA HOSPITAL SICHUAN UNIV
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Problems solved by technology

However, this study focused on describing the differences that may be caused by various surgical options from a statistical point of view, and did not recommend individualized surgical orthopedic options for each patient, nor did it provide specific orthopedic values ​​for the curvature of the spine. optimization suggestions
The biggest limitation of similar biomechanical research is that it is necessary to manually select the value or category range of the included variables. The process is quite cumbersome and inefficient, and it is not possible to automatically optimize the numerical value selection for a given range interval.

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  • Spine near-end boundary angle operation optimization method based on finite elements and machine learning
  • Spine near-end boundary angle operation optimization method based on finite elements and machine learning
  • Spine near-end boundary angle operation optimization method based on finite elements and machine learning

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Embodiment Construction

[0041] In order to make the object, technical solution and advantages of the present invention clearer, the present invention will be further described in detail below in conjunction with the accompanying drawings.

[0042] The surgical optimization method of the proximal junction angle of the spine based on finite element and machine learning includes the following steps:

[0043] Step s1: collecting patient information, the information includes the patient's gender, age, weight, preoperative CT, preoperative full spine X-ray and postoperative full spine X-ray.

[0044] Step s2: performing image segmentation on the preoperative CT.

[0045] In step s2, performing image segmentation on the preoperative CT refers to importing the patient's preoperative CT into the Mimics software and automatically segmenting the annulus fibrosus and nucleus pulposus of the uppermost fixed vertebral head end intervertebral disc. Such as figure 1 as shown, figure 1 Segmentation rendering of th...

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Abstract

The invention discloses a spine near-end boundary angle operation optimization method based on finite elements and machine learning. The spine near-end boundary angle operation optimization method comprises the following steps: s1, collecting patient information; s2, carrying out image segmentation on the preoperative CT; s3, respectively measuring the PJA angle alpha of the patient from the preoperative total spinal X-ray and the postoperative total spinal X-ray of the patient; s4, calculating the pressure F borne by the patient before and after the intervertebral disc operation under the upright condition, wherein the head end of the vertebral body is fixed at the uppermost end of the intervertebral disc; s5, carrying out static analysis; s6, establishing a machine learning model g (.) according to the patient information and the stress distribution change data obtained in the step s3; s7, training the machine learning model g (.); and s8, obtaining an optimal solution of the postoperative PJA. According to the method, the advantages of finite element stress analysis and machine learning efficient simulation are combined, and an automatic, personalized and accurate operation scheme optimization method is provided for a patient.

Description

technical field [0001] The invention relates to the technical field of medical image processing, in particular to an operation optimization method for the proximal junction angle of the spine based on finite elements and machine learning. Background technique [0002] Spinal fixation devices for the treatment of spinal deformities continue to evolve with the advent of new device designs, providing surgery with many options for correction. These changes have led to innovations in many surgical protocols, including the selection of proximal and distal fusion segments, the type of implant, and the choice of internal fixation device material. Most of the newly published patents are aimed at the improvement of surgical instruments, such as Chinese patent CN110916732A, a kind of protective cover for spinal surgery drag hooks, and CN110338897A, a kind of adjustable bending plate for orthopedic scoliosis surgery. However, the biomechanical effects of each component in a complex sur...

Claims

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Application Information

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IPC IPC(8): G16H50/50G06T7/11G16H50/30
CPCG16H50/50G06T7/11G16H50/30G06T2207/30012
Inventor 彭丽张广铭周小波
Owner WEST CHINA HOSPITAL SICHUAN UNIV
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