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Bones of the Upper Limb: Humerus01:19

Bones of the Upper Limb: Humerus

11.3K
The upper limb consists of the arm, forearm, wrist, and hand bones. The humerus is the single bone of the upper arm region. Proximally, it has a large, spherical, smooth head that articulates with the glenoid cavity of the scapula to form the glenohumeral or shoulder joint. The margin of the head is the anatomical neck, a residual epiphyseal plate. Laterally it extends to form bony projections called the greater tubercle and the lesser tubercle. Next to the tubercles is the surgical neck, a...
11.3K
Muscles of the Shoulder01:23

Muscles of the Shoulder

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The muscles surrounding the shoulder girdle, including the clavicle and scapula, primarily stabilize the scapula. This stable base allows other muscles to move the humerus effectively. Scapular movements often mirror those of the humerus and extend its range of motion. For instance, raising the arm above the head would not be feasible without simultaneous upward rotation of the scapula.
Anterior Thoracic Muscles
The anterior thoracic muscles include the serratus anterior, subclavius, and...
9.4K
Muscles that Move the Arm01:31

Muscles that Move the Arm

5.5K
Nine muscles are involved in arm movements. Two of these, the pectoralis major and latissimus dorsi, originate from the axial skeleton and are called axial muscles. The other seven originate from the scapula and are called the scapular muscles.
The pectoralis major has two origins. Its clavicular head originates on the medial half of the clavicle. In contrast, the sternocostal head originates on the costal cartilages of ribs 1-6, the sternum, and the aponeurosis of the external oblique of the...
5.5K
Bones of the Upper Limb: Ulna01:15

Bones of the Upper Limb: Ulna

8.9K
The ulna and radius are parallel bones of the antebrachium or the forearm. The ulna lies medially and consists of a bony tip called the olecranon process at its proximal end. This hook-like projection articulates with the olecranon fossa of the humerus and forms the "hinged" ulnohumeral part of the elbow joint. This joint facilitates forearm extension and flexion while preventing its hyperextension. Similarly, the coronoid process, another bony projection on the proximal/anterior side...
8.9K
Bones of the Lower Limb: Femur and Patella01:16

Bones of the Lower Limb: Femur and Patella

8.2K
The femur is the body's longest and strongest bone spanning the thigh region. Its head articulates with the acetabulum of the hip bone to form the hip joint. A minor indentation on the medial side of the femoral head, called the fovea capitis, serves as the site of attachment for the ligament of the head of the femur. This weak ligament spans the femur and acetabulum and supports the hip joint. The narrowed region below the head is the neck of the femur. The inclination angle between the...
8.2K
Maximum Deflection01:13

Maximum Deflection

1.2K
When analyzing beams under unsymmetrical loads, such as a train moving on a bridge, it is crucial to accurately determine the points of maximum stress and deflection. The process involves identifying the maximum deflection of the beam, which may not always occur at its midpoint due to the uneven distribution of the load.
The maximum deflection occurs at a specific point, known as point O, where the tangent to the deflection curve is horizontal. To find point O, the slope of the tangent at any...
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Related Experiment Video

Updated: May 3, 2026

Measuring 3D In-vivo Shoulder Kinematics using Biplanar Videoradiography
06:09

Measuring 3D In-vivo Shoulder Kinematics using Biplanar Videoradiography

Published on: March 12, 2021

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Glenohumeral relationship in maximum elevation.

Hiroaki Inui1, Katsuya Nobuhara

  • 1Nobuhara Hospital and Institute of Biomechanics, 720 Haze, Issaicho, Tatsunoshi, Hyogo, 679-4017, Japan, inuhiro123@yahoo.co.jp.

Surgical and Radiologic Anatomy : SRA
|January 25, 2014
PubMed
Summary

The glenohumeral joint locks in axial rotation before maximum elevation. Beyond this point, the joint translates without further rotation, indicating a fixed final elevation position.

Area of Science:

  • Orthopedics
  • Biomechanics
  • Human Anatomy

Background:

  • Understanding the complex biomechanics of the glenohumeral joint is crucial for diagnosing and treating shoulder pathologies.
  • The rotational dynamics during maximum arm elevation remain incompletely understood.

Purpose of the Study:

  • To elucidate the rotational relationships between anatomical landmarks of the glenohumeral joint during maximum elevation.
  • To investigate glenoid location and rotational behavior relative to the humeral head.

Main Methods:

  • Utilized an open MRI system with 25 healthy volunteers (20 men, 5 women; mean age 31).
  • Generated 3D computer images to measure humerus elevation angle in the plane of elevation relative to glenoid and scapular planes.
  • Defined humeral head equator and investigated glenoid position and rotational relationships.

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Main Results:

  • Maximum elevation angle averaged 102° ± 9°, occurring 7° ± 8° anterior to the scapular plane.
  • Axial rotation was fixed, with the glenoid long axis parallel to the humeral head equator (within 2°).
  • Glenoid center was located antero-superiorly on the humeral head, translating without rotation after reaching the equator.

Conclusions:

  • The glenohumeral joint achieves a locked axial rotation state before maximum elevation.
  • The final elevation position is defined by the glenoid atop the humeral head with the humeral shaft perpendicular.
  • Further elevation beyond this point involves translation without additional axial rotation of the glenohumeral joint.