Elbow Joint Anatomy: A Comprehensive Guide to Osseous Structure

The elbow represents a complex hinge joint that combines stability with mobility to enable essential upper extremity functions. This intricate articulation between the humerus, radius, and ulna facilitates both flexion-extension movements and forearm rotation, making it crucial for activities of daily living and specialized tasks.

Anatomical Labels and Their Functions:

Humerus The humerus forms the upper component of the elbow joint. Its distal end contains specialized articular surfaces for both the radius and ulna.

Lateral Epicondyle The lateral epicondyle serves as an attachment point for the common extensor tendons. It’s frequently involved in tennis elbow pathology.

Capitellum The capitellum is a rounded articular surface that articulates with the radial head. It enables smooth forearm rotation during pronation and supination.

Head (Radial) The radial head articulates with the capitellum and proximal ulna. It’s crucial for load transmission and forearm rotation.

Neck (Radial) The radial neck connects the head to the shaft. It’s a common fracture site in children and provides attachment for the annular ligament.

Tuberosity The radial tuberosity provides attachment for the biceps tendon. It’s essential for supination force transmission.

Olecranon The olecranon forms the tip of the elbow and provides leverage for the triceps muscle. It’s crucial for elbow extension power.

Trochlear Notch The trochlear notch articulates with the humeral trochlea. It provides stability during flexion-extension movements.

Coronoid Process The coronoid process forms the anterior part of the trochlear notch. It acts as an anterior buttress preventing posterior elbow dislocation.

Radial Lesser Sigmoid Notch This notch articulates with the radial head. It enables smooth pronation-supination movements.

Supinator Crest The supinator crest provides attachment for the supinator muscle. It’s essential for forearm supination movements.

Radius The radius is the lateral forearm bone. It enables forearm rotation and wrist movements.

Ulna The ulna is the medial forearm bone. It provides stability for elbow flexion-extension.

Elbow Joint Biomechanics

The elbow functions as both a hinge and pivot joint. Understanding its complex biomechanics is essential for clinical practice and surgical intervention.

Joint Articulations

The elbow complex consists of three distinct joints:

• Ulnohumeral joint (hinge movement)
• Radiocapitellar joint (rotation)
• Proximal radioulnar joint (forearm rotation)

Movement Parameters

Primary movements include:

• Flexion (0-145 degrees)
• Extension (145-0 degrees)
• Pronation (0-80 degrees)
• Supination (0-85 degrees)

Clinical Applications

Common Pathologies

Elbow disorders frequently encountered include:

• Tennis elbow (lateral epicondylitis)
• Golfer’s elbow (medial epicondylitis)
• Distal biceps rupture
• Olecranon bursitis
• Ulnar nerve entrapment

Diagnostic Approaches

Modern evaluation techniques incorporate:

• Advanced imaging (MRI/CT)
• Dynamic ultrasound
• Stress radiography
• Electrodiagnostic studies
• Motion analysis

Surgical Considerations

Approach Selection

Surgical planning requires assessment of:

• Neurovascular structures
• Muscle planes
• Joint stability
• Fracture patterns
• Soft tissue integrity

Rehabilitation Protocols

Treatment strategies emphasize:

• Protected motion
• Staged strengthening
• Return to function
• Prevention of stiffness
• Sport-specific training

1. Elbow Joint Anatomy: A Clinical Guide for Medical Professionals
2. Understanding Elbow Biomechanics: From Structure to Function
3. Comprehensive Guide to Elbow Joint Architecture
4. Elbow Anatomy: Essential Knowledge for Orthopedic Practice
5. Clinical Analysis of Elbow Joint Structure and Function