Wednesday, June 28, 2023

Towards rapid tissue regeneration


DTU researchers create a scaffold for instant healing of bone.

Peer-Reviewed Publication

TECHNICAL UNIVERSITY OF DENMARK

Bone structure and composition and biomimetic scaffold developmentg 

IMAGE: FIGURE 1. (A) SCHEMATIC REPRESENTATION OF THE (A) BONE STRUCTURE AND ITS COMPOSITION RANGING FROM NANOMETERS TO MICROMETRES AND (B) DEVELOPMENT OF BIOMIMETIC SCAFFOLDS CONTAINING THE VARIOUS STEPS FOR PREPARING A COMBINATORIAL HYDROGEL/SCAFFOLD. HTTPS://PUBS.ACS.ORG/DOI/FULL/10.1021/ACSAMI.3C01717 view more 

CREDIT: ILLUSTRATION: DOLATSHAHI-PIROUZ ET AL.



A team at DTU Health Tech led by Associate Professor Alireza Dolatshahi-Pirouz have made a leap forward in tissue regeneration by creating a multi-levelled scaffold that encompasses properties of native bone on both the nano, micro and macro scale.

In a recent paper in the ACS Applied Materials and Interfaces journal, the researchers describe the discovery of near-perfect bone healing in a rat model after only eight weeks, using their scaffold—and without using growth factors.

In addition, the scaffold is combinatorial and can simultaneously release several essential bone minerals while covering mechanical properties, i.e., the compressive strength needed to match those of cancellous human bone.

The implications of these results are enormous, and our aim is now to lower the healing time to 4 weeks and reach almost instant tissue regeneration without using endocrine factors and cells. We will also be looking into whether this could be used for other tissues," says Associate professor at DTU Health Tech and corresponding author Alireza Dolatshahi-Pirous.

FDA approved materials

By incorporating stem cells, more bioactive components such as collagen and gelatin, coatings that increase native cell migration into the scaffolds, and electromagnetic stimulation, it could pave the way for rapid healing of soldiers suffering from critical musculoskeletal fractures or civilians suffering from traumatic injuries. These people are hospitalized for months, with a long road to recovery.

Notably, this new scaffold was made primarily from glass, alginate and nano silicate— already FDA-approved materials. Thanks to its FDA-approved status, hurdles for regulatory clearance are significantly reduced. This means the scaffold can be used more confidently and efficiently in clinical settings, accelerating development and improving patient outcomes.

"I believe this discovery could be a game-changer in the field of tissue regeneration, and I hope to see this technology being used to help those in need," says Alireza Dolatshahi-Pirouz.

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