3-D-printed bone implant can get dissolved in the body

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rtr43aamThe developers plan to use the new implants in oral and maxillofacial surgery to replace small parts of skull bones, up to five cubic centimeters in size.

In a major step towards improving surgeries after head or face injuries, Russian scientists have recently developed a new type of 3-D-printed polymeric bone implants that can get absorbed and subsequently replaced with natural bone tissue in the body. The prototype can be printed on 3D-printers according to specific parameters, contracted to half its size, then heated in the course of the surgery so the implant can obtain its original shape and size and is securely fixed in the section of the bone being restored. The implant is installed with a minimum number of metal fixators that are traditionally used in transplantation.

“We have successfully employed the shape memory effect of the lactic acid polymer – a composite based on polylactide. The porous composite structure is capable of shrinking to half its original size and then returning to its original shape,” Project Manager Fyodor Senatov National University of Science and Technology MISIS in Moscow, said in a statement.

“This material is bioresorbable: it decomposes in the body without causing any harm,” Senatov noted. The researchers noted in traditional implant insertion after a head injury, additional surgery is often required due to the low rate of integration with the surrounding tissues or wrong implant position.

The newly invented polymeric implant has a specified geometry and high porosity, and does not require any additional treatment, the researchers said. Due to the properties of the material and the use of the patient’s own cells, it rapidly adapts and gets replaced with natural bone tissue.

“Together with specialists at the N.N. Blokhin Russian Cancer Research Center, we have developed the technique of colonising the bioengineered structure with cells isolated from the patient’s bone marrow,” Senatov said. “The preliminary colonization stimulates budding of blood vessels and tissues inside the implant, which optimises the process and increases the rate of integration with the surrounding tissues, making for more effective transplantation,” Senatov said.

The developers plan to use the new implants in oral and maxillofacial surgery to replace small parts of skull bones, up to five cubic centimeters in size. The estimated cost of a bioengineered structure colonized with cells isolated from the patient’s bone marrow is about $400, the researchers said.

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