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Functional Classification of Joints01:09

Functional Classification of Joints

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Functional Classification of Joints
The functional classification of joints is determined by the amount of mobility between the adjacent bones. Joints are functionally classified as a synarthrosis or immobile joint, an amphiarthrosis or slightly moveable joint, or as a diarthrosis, a freely moveable joint. Fibrous and cartilaginous joints can be functionally classified as either synarthroses  or amphiarthroses, whereas all synovial joints are classified as diarthroses.
Synarthrosis
An...
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Structural Classification of Joints01:20

Structural Classification of Joints

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Joints, also known as articulations, are classified based on their structural characteristics, i.e., based on whether the articulating surfaces of the adjacent bones are directly connected by fibrous connective tissue or cartilage, or whether the articulating surfaces contact each other within a fluid-filled joint cavity. These differences serve to divide the joints of the body into three structural classifications.
A fibrous joint is where the adjacent bones are united by fibrous connective...
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Related Experiment Video

Updated: May 2, 2026

Automated Midline Shift and Intracranial Pressure Estimation based on Brain CT Images
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Large Separable Kernel Attention-Driven Multidimensional Feature Cross-Level Fusion Classification Network of Knee

Lirong Zhang1, Hang Yu1, Yating Yang1

  • 1The School of Digital Art and Design, Dalian Neusoft University of Information, No. 8 Software Park Road, Ganjingzi District, Dalian, Liaoning, 116023, China, 86 13478427287.

JMIR Medical Informatics
|December 17, 2025
PubMed
Summary
This summary is machine-generated.

This study introduces a deep learning model using magnetic resonance imaging (MRI) for accurate knee cartilage injury (KCI) classification. The advanced AI network achieves over 99% accuracy, improving early diagnosis and clinical application.

Keywords:
cross-level fusionknee cartilage injurylarge separable kernel attentionmultidimensional featuremultilevel classification

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Area of Science:

  • Orthopedics
  • Radiology
  • Artificial Intelligence
  • Medical Imaging

Background:

  • Knee cartilage injury (KCI) presents diagnostic challenges due to high incidence and limited imaging sensitivity.
  • Early and accurate diagnosis is crucial for effective treatment and management of KCI.

Purpose of the Study:

  • To enhance the classification accuracy of knee cartilage injuries using magnetic resonance imaging (MRI) and machine learning.
  • To develop an improved deep learning network structure for precise KCI diagnosis.
  • To demonstrate the clinical utility of advanced AI in diagnosing KCI.

Main Methods:

  • A novel multidimensional feature cross-level fusion classification network incorporating large separable kernel attention within the YOLOv8 architecture was developed.
  • The network fuses shallow, high-resolution features with deep semantic features for enhanced hierarchical characterization of cartilage damage.
  • Deep learning techniques were applied to a unique hospital-based, multidimensional MRI dataset for KCI.

Main Results:

  • The proposed deep learning model achieved exceptional classification performance on a real-world KCI dataset.
  • Key performance metrics included 99.7% accuracy, 99.6% Kappa statistic, 99.7% F-measure, 99.7% sensitivity, and 99.9% specificity.
  • Experimental validation confirmed the feasibility and high precision of the developed diagnostic method.

Conclusions:

  • The developed methodology significantly improves knee cartilage injury classification accuracy compared to existing techniques.
  • The high performance and potential for clinical deployment highlight its value in enhancing diagnostic precision and efficiency for KCI.
  • This AI-driven approach shows promise for revolutionizing early detection and management of knee cartilage injuries.