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Hydrothermal synthesis of valve metal Zr-doped titanate nanofibers for bone tissue engineering

Parker Cole, Yang Tian, Savannah Thornburgh, Mary Malloy, Lauren Roeder, Micah Maulding, Yang Huang, Z. Ryan Tian

Abstract


Investigations are underway to identify novel biomaterials to improve strategies for bone tissue engineering. Hybrid nanomaterials have emerged as a viable class of biomaterials. Here, we report a facile, economical, optimized, and well-controlled hydrothermal method for synthesizing Zr-doped potassium titanate nanofibers with high purity. Upon morphological characterization, Zr-doping did not disrupt the parent crystal structure of potassium titanate, which showed huge potential for bone tissue engineering.

Keywords

nanosynthesis; titanate nanofiber; bone tissue engineering; bone-scaffold; zirconium doping

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References

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DOI: https://doi.org/10.59400/nmm.v3i2.249
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Copyright (c) 2023 Parker Cole, Yang Tian, Savannah Thornburgh, Mary Malloy, Lauren Roeder, Micah Maulding, Yang Huang, Z. Ryan Tian

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