Features
The Intracerebral Haemorrhage is a clinically accurate 3D printed brain model created for medical educators, students, and healthcare professionals. It provides a tangible, detailed representation of a haemorrhagic stroke, demonstrating pathology and neuroanatomy to enhance understanding. Choose this model for its educational value and uncompromising realism in displaying complex brain injuries.
Examine Realistic Brain Pathology with the Intracerebral Haemorrhage Model
This 3D printed anatomical model captures the devastation of a massive intracerebral haemorrhage. It details the rupture in the left basal ganglia and internal capsule, extending into the lateral ventricles. The model highlights the displacement of midline structures and the resulting subfalcine herniation, providing a true-to-life learning tool. Medical students, educators, and clinicians gain important visual and tactile insight into complications from systemic hypertension. Every element, from the coronal brain sections to the visibly expanded left hemisphere, supports accurate neurological assessment and teaching.
Features and Benefits
- 3D printed from clinical-grade scans for maximum anatomical accuracy
- Shows coronal sections at the mammillary body and temporal lobes, including brainstem details
- Highlights a massive blood clot replacing the left basal ganglia and internal capsule
- Depicts rupture into both lateral ventricles and damage to surrounding brain tissue
- Demonstrates midline shift and subfalcine herniation of cingulate gyrus
- Materials allow hands-on examination and repeated classroom use
- Ideal for neurology, pathology, and anatomy education
Indications for Use
- Medical and nursing education on haemorrhagic stroke
- Neuroanatomy and pathology demonstrations
- Simulation-based training for clinicians
- Patient and family education about intracerebral haemorrhage
Size Guide
- Single model representing an adult male brain
- Coronal sections at the level of the mammillary bodies, cerebral peduncles, and temporal lobes
- Full-scale anatomical replication for clinical accuracy


















