Biomechanical Study of Lever Positioning Manipulation on Scoliosis

Summary

Research background Scoliosis is a common three-dimensional spinal deformity, especially in adolescents. In severe cases, it can lead to thoracic deformation and cardiopulmonary dysfunction. At present, clinical treatment is mainly based on Cobb angle to take observation, brace or surgical intervention, but there are problems such as poor compliance and large trauma. As a non-invasive massage therapy, leverage positioning manipulation has shown orthopedic effects in clinical practice, but its biomechanical mechanism has not been systematically quantified, which restricts its standardization and promotion.

Purpose of the study The purpose of this study is to quantify the mechanical and kinematic parameters of lever positioning manipulation in the treatment of scoliosis through biomechanical testing and finite element simulation technology, to construct an individualized finite element model, to analyze the stress and strain distribution of each structure of the spine under the intervention of manipulation, to reveal its biomechanical mechanism, and to provide scientific basis for the standardization of manipulation and the optimization of curative effect.

Research contents and methods The study is divided into two parts : In the first part, 30 patients with scoliosis were recruited. Through the integrated mechanical sensor and motion capture system, the mechanical parameters ( such as preload force, maximum pull force ) and kinematic parameters ( such as angle, angular velocity ) during the manipulation were recorded in real time. In the second part, based on the CT data of patients, the three-dimensional finite element model of T10-L2 segment was constructed by using Mimics, Geomagic, SolidWorks and ANSYS software to simulate the loading process of manipulation and analyze the stress and strain response of vertebral body, intervertebral disc and ligament complex under the action of manipulation.

Expected results and significance This study will systematically quantify the biomechanical characteristics of lever positioning manipulation for the first time, and clarify its mechanism of action in the treatment of thoracolumbar scoliosis. Through the finite element simulation, the stress distribution is visualized, which provides data support for the precision and individualization of manipulation, promotes the transformation of massage manipulation from ' experience dependence ' to ' quantitative science ', and lays a theoretical foundation for the development of intelligent orthopedic equipment in the future.

Ethics and quality control The study has passed the ethical review, and all participants will sign the informed consent. The manipulation was performed by the same experienced physician, and the data collection and analysis process was strictly controlled to ensure that the results were true and reliable.

Conditions

• Scoliosis

Interventions

PROCEDURE

Lever positioning manipulation

1 The patient took the prone position, exposed the waist and back, relaxed the whole body, and straightened the lower limbs. 2 The surgeon determined the top vertebra of the scoliosis according to the whole spine X-ray film, and used the olecranon of the elbow as the force fulcrum to accurately press the transverse process or spinous process on the convex side of the top vertebra, and the assistant fixed the shoulder of the patient. 3 The patient was asked to open his mouth and exhale, and the operator lifted the patient 's lower limbs on the other hand. Through the force arm conduction of the lower limbs-pelvis-spine, the lower limbs were lifted obliquely above the convex side to form a force arm lever. 4 When pulling to the resistance point, the surgeon pulled quickly with inch force. After the operation, the patient was allowed to rest in a prone position for 10 minutes.

Sponsors & Collaborators

• Zhejiang Chinese Medical University

  collaborator OTHER_GOV

• The Third Affiliated hospital of Zhejiang Chinese Medical University

  lead OTHER

Study Design

Allocation

NA

Purpose

TREATMENT

Masking

NONE

Model

SINGLE_GROUP

Eligibility

Min Age

10 Years

Max Age

45 Years

Sex

ALL

Healthy Volunteers

No

Timeline & Regulatory

Start

2026-01-10

Primary Completion

2028-06-30

Completion

2028-12-31

Countries

• China

Study Locations