Cyberbone

#implants #neurosurgery #biomaterials More than 14 days ago, a procedure took place in Kyiv with the replacement of a skull bone defect in a 13-year-old girl. Bone defect - after oncological treatment. A personalized, bioresorbable 3D printed implant with a porous surface was used. The procedure took place successfully. Unfortunately, during the procedure, the doctor noticed a disturbing change in the tissues. After histopathological examination, we know that it is a recurrence. MRI performed a month ago showed nothing. The child will now be quickly treated by “radiation”. The implant is resistant to radiation. We are waiting for the happy result of oncological treatment and later regeneration.

#biomaterials #neurosurgery #implants #3Dprinting We are beginning efforts to obtain FDA approval for personalized, bioresorbable, 3D printed implants for bone regeneration in children.  There is hard work ahead, but we believe we will be successful.

#3dprinting #hydrogels #biomaterials Combining 3D printing technologies from bioresorbable biomaterials and chitosan hydrogels. The highly porous structure of the print allows the hydrogel to be absorbed and cross-linked. Planned result - faster and more stable tissue remodeling. Also soft tissues. Both technologies have clinical validation.

Next article on bioresorbable 3D printed implants from the period of the research project. "Accelerated Aging Effect on the Stability of the 3D-Printed Biodegradable Implant for Bone Defect Repairs." Thank you to our research partners at Instytut Technologii Bezpieczeństwa "MORATEX".

We will have a presentation of our project at the webinar “Bio-inspired technologies and smart materials” - January 23, 2025. We invite you to join us.

Great review on modern polymer technologies in medicine. Co-authors are our researchers from the project - ladies #MonikaDobrzyńskaMizera and #MonikaKnitter. It's also about our #Cyberbone.

#3Dprinting #cranioplasty #implants #biomaterials 3D printed " perforated - porous" personalized implant for cranioplasty. Manufactured by FDM method. The filament is PLDL with HA filler.

#biomaterials #microporous #invivo #implants Here's a short post about our 2009-2010 in vivo study of microporous membranes (pellets) made of polylactide copolymer Corbion Biomaterials Authored by: Prof. Sylwester Gogolewski and Prof. Krzysztof Ficek MD (head of the Galen-Ortopedia clinic).

#biomaterials #microporous #orthopeadics #implants Several years ago, prior to the cycle of clinical trials, we conducted an in vivo study together with Galen-Ortopedia in Bierun from the application of microporous (50%) sponges/membranes manufactured from a copolymer of polylactide Corbion Biomaterials Studies on rabbits - ACL reconstructions. Below briefly from the presentation the results.

#biomaterials #implants #boneregeneration This is how the manufacture of microporous membranes from polylactide copolymer looks like in a shortcut. It can be formed at the manufacturing stage. Alternatively, they can be easily formed into any shape after fabrication.