Pinoy researchers advance bone repair with AI and 3D

Filipino researchers are using artificial
intelligence (AI) and 3D
printing technologies to
enhance bone tissue repair, providing a more accessible and affordable
solution for bone related
challenges caused by aging, infections, and accidents.
Aiming to empower patients and doctors in selecting the optimal bone repair material
based on medical needs
and affordability, this project offers a more viable alternative to existing methods by providing enhanced
performance for complex
bone regeneration using
3D printing technology to
craft bone scaffolds with
tunable shapes.
Led by Dr. Erwin
P. Enriquez of the Ateneo de Manila University
(AdMU), and supported
by the Philippine Council
for Health Research and
Development (PCHRD),
the team leverages on an
international collaboration
with researchers from the
Vellore Institute of Technology in India, that specializes in additive manufacturing, AI-assisted
design, and bio-nanotechnology using 3D printing
technology.
In its second
year, the project has developed a machine-learning model to analyze
factors affecting the effectiveness of bioceramic precursor materials in
printing. Simultaneously,
the team explores polymer-nano clay materials
and 3D-printed frameworks, ensuring strength
and compatibility with the
human body.
“By integrating
transformative technologies like AI and 3D printing, we are charting a
course towards a future
where healthcare is revolutionized, and innovative
approaches become the
cornerstone of medical
advancements. This collaborative initiative, showcasing the dedication and
expertise of our team,
holds promise in providing
accessible and affordable
solutions for bone-related challenges.,” stated
Dr. Jaime C. Montoya,
PCHRD Executive Director.
Recognizing the
limitations of traditional
transplantation, the researchers advocate for a
shift towards regeneration
as a more promising solution for damaged tissues
and organs. The project,
set to conclude in August
2024, focuses on refining
additive manufacturing
and processing techniques, aiming to significantly reduce fabrication
time compared to current
technologies.
Once successful,
this initiative may empower surgeons with a diverse
selection of composite
materials, custom-tailored
to meet the medical and financial needs of individual
patients. END