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Can we make bones heal faster?

New real-time images of bone, tooth formation

Date:
December 3, 2020
Source:
University of Illinois at Chicago
Summary:
A new article describes for the first time how minerals come together at the molecular level to form bones and other hard tissues, like teeth and enamel.
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A new paper in Science Advances describes for the first time how minerals come together at the molecular level to form bones and other hard tissues, like teeth and enamel.

The University of Illinois Chicago researchers who published the paper described their experiments -- which captured high-resolution, real-time images of the mineralization process in an artificial saliva model -- and their discovery of distinct pathways that support bone and teeth formation, or biomineralization.

"Until now these pathways, particularly at the early stages when molecules are first starting to organize into a structure, have not been understood clearly," Reza Shahbazian-Yasser, UIC professor of mechanical and industrial engineering at the College of Engineering and corresponding author of the paper.

Shahbazian-Yasser and his colleagues observed that both direct and indirect formations of hydroxyapatite crystals -- the foundation of hard tissues -- can be achieved by local variations in energetic pathways for nucleation and growth.

"The control over the dissolution of amorphous calcium phosphate affects the assembly of hydroxyapatite crystals into larger aggregates," Shahbazian-Yasser said. "Using technology developed at UIC, we found evidence that these pathways coexist simultaneously -- explaining why different groups had reported seemingly different or opposite results. In addition, we now understood how hydroxyapatite materials nucleate and grow on amorphous calcium phosphate templates. The control over the nucleation and growth of hydroxyapatite will aid in developing new drugs and medical treatments to heal lost or broken bone faster or cure tooth cavities."

To capture the images, the researchers used a unique micro-device that made it possible to use electron microscopy with a liquid model. Using this method, the researchers were able to monitor chemical reactions in the model on the smallest scale.

"Our study provides clear, new evidence of how minerals organize and grow into bone materials, and this finding has many important implications for further research on bone or teeth healing," Shahbazian-Yasser said.

"By better understanding these pathways, scientists are one step closer to engineering ways to better treat dental diseases and bone injuries -- like those from traumatic injuries -- or prevent medical conditions that can develop when normal mineralization processes in the body go awry," he said.

Medical conditions caused by dysfunctional mineralization in the body can include everything from a tendency to develop cavities to osteoporosis.

"In the next step, we would like to learn how molecular modifiers can affect the process of biomineralization, which is important to develop effective drugs," Shahbazian-Yasser said.


Story Source:

Materials provided by University of Illinois at Chicago. Note: Content may be edited for style and length.


Journal Reference:

  1. Kun He, Michal Sawczyk, Cong Liu, Yifei Yuan, Boao Song, Ram Deivanayagam, Anmin Nie, Xiaobing Hu, Vinayak P. Dravid, Jun Lu, Cortino Sukotjo, Yu-peng Lu, Petr Král, Tolou Shokuhfar, Reza Shahbazian-Yassar. Revealing nanoscale mineralization pathways of hydroxyapatite using in situ liquid cell transmission electron microscopy. Science Advances, 2020; 6 (47): eaaz7524 DOI: 10.1126/sciadv.aaz7524

Cite This Page:

University of Illinois at Chicago. "Can we make bones heal faster?." ScienceDaily. ScienceDaily, 3 December 2020. <www.sciencedaily.com/releases/2020/12/201203144112.htm>.
University of Illinois at Chicago. (2020, December 3). Can we make bones heal faster?. ScienceDaily. Retrieved November 22, 2024 from www.sciencedaily.com/releases/2020/12/201203144112.htm
University of Illinois at Chicago. "Can we make bones heal faster?." ScienceDaily. www.sciencedaily.com/releases/2020/12/201203144112.htm (accessed November 22, 2024).

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