To create the most realistic, patient-specific simulation for surgical training, vascular models must mimic how native tissue responds to pressure, punctures, and stitches
View more3D anatomical models don’t require regulatory ethical requirements (or a facility to handle the biohazards and sterilization) and offers longevity and reduced cost compared to ex-vivo and in-vivo cadaveric animal testing.
View moreResearchers at the Computational Mechanics and Experimental Biomechanics Lab tested the accuracy and realism of J750 Digital Anatomy printed bone models.
View moreTo create the most realistic, patient-specific simulation for surgical training, vascular models must mimic how native tissue responds to pressure, punctures, and stitches
3D anatomical models don’t require regulatory ethical requirements (or a facility to handle the biohazards and sterilization) and offers longevity and reduced cost compared to ex-vivo and in-vivo cadaveric animal testing.
Researchers at the Computational Mechanics and Experimental Biomechanics Lab tested the accuracy and realism of J750 Digital Anatomy printed bone models.
The Centre for Biomedical Technology and Integration (CBMTI) uses PolyJet technology to closely simulate tissue and create a realistic surgical scenario fro training situations. With the help of the J750 printer to provide a variation in texture and color it creates a viable alternative to for training.
The hospital for Sick Children uses lifelike 3D printed models for pre-surgical practice. Now by the time surgeons perform cardiac surgery on children, they are already expert performers for the procedures.
Watch the video to learn more.