Features
The Shoulder – deep dissection of the left shoulder joint, musculature, and associated nerves and vessels is a highly detailed 3D printed anatomical model for educators, clinicians, and students. It models an expert-level dissection that reveals key musculoskeletal and neurovascular elements, helping users understand complex shoulder anatomy. Choose this model for unmatched accuracy and teaching value when you need clear visualization of the left shoulder’s internal structures.
Unlock Comprehensive Shoulder Anatomy with Unparalleled Detail
This clinical-grade 3D printed model offers an advanced view into the left shoulder’s internal composition. The Shoulder – deep dissection of the left shoulder joint, musculature, and associated nerves and vessels displays the scapula, proximal humerus, and surrounding muscles, nerves, and blood vessels with remarkable fidelity. The model features a meticulously removed deltoid muscle, exposing rotator cuff tendons and deep joint structures that are challenging to access in standard classroom models. With vibrant color and true-to-life form, health professionals and students can explore anatomy with greater confidence and insight.
Features and Benefits
- 3D printed for precision and durability
- Accurate deep dissection reveals underlying shoulder, nerve, and vessel structures
- Deltoid muscle removed to showcase rotator cuff anatomy
- Includes scapula and proximal humerus to near midshaft
- Clinical-grade detail, suitable for advanced teaching and study
- Available with optional detailed anatomical description
- Ideal for demonstration, instruction, and reference
- Fast Australian delivery and free shipping on orders over $150
Indications for Use
- Medical and allied health education
- Surgical anatomy demonstration
- Musculoskeletal reference for clinicians
- Student anatomical study and exam preparation
- Patient education in clinical settings
Size Guide
- Life-size anatomical model
- Replicates the left shoulder region including scapula and proximal humerus (to near midshaft)
- Model dimensions match actual anatomical structures for realistic study





















