Integration of Biomechanical Sensor in Spinal Brace for Posture Detection and Correction

Over the past decade, 60% of people have been affected by spinal curvature at some point in their lives. It is a disease of the spine bones such as kyphosis, lordosis, and scoliosis that affects humans and occurs most commonly in adults, although the cause of most childhood cases is unknown. Everyon...

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Bibliographic Details
Published in2025 International Conference on Artificial Intelligence and Data Engineering (AIDE) pp. 979 - 984
Main Authors Sivamani, C., M, Santhosh, M, Vasanth, K, Arulmozhi, V, Abinaya
Format Conference Proceeding
LanguageEnglish
Published IEEE 06.02.2025
Subjects
Back
biocompatibility
Biomechanics
Biosensors
detection
flexibility supportive
Intelligent sensors
Pain
Real-time systems
Scoliosis
Sensor systems
Spinal corrective brace
Ventilation
X-rays
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DOI10.1109/AIDE64228.2025.10986818

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Summary:Over the past decade, 60% of people have been affected by spinal curvature at some point in their lives. It is a disease of the spine bones such as kyphosis, lordosis, and scoliosis that affects humans and occurs most commonly in adults, although the cause of most childhood cases is unknown. Everyone has some degree of curvature, but when it exceeds about certain degrees, it causes turbulence and difficulty breathing. It is diagnosed by methods such as X-rays and other measurements. It is treated using a variety of techniques, such as Back support requires less adjustment and is more comfortable. This may cause back pain, injury, and ventilation insufficiency for the person wearing the brace. The main goal of our research is to develop a spinal brace with circuits to detect the biomechanical properties of the spine in order to develop innovative and improved functions. The proposed system used for detection spinal curvature angle using biomechanical sensors like IMU and flex sensors. The sensor data is processed by NodeMCU so that the data can be compared with real-time data. When a difference is detected, a signal is passed to a vibrator and it begin alert. Furthermore, the system enhances the automatic correction with pressure cuff mechanism. The developed system overcome the disadvantages of traditional construction methods and proposes a model with high flexibility, strength, durability, and breathability. The system is resulting in less pain, better ventilation, and increased comfort and adjustability. The conclusion marks that the system has better efficiency and effectiveness in usage, which made bridge between gap of clinical and remote assessment
DOI:10.1109/AIDE64228.2025.10986818