Characterization of hydrogel-scaffold mechanical properties and microstructure by using synchrotron propagation-based imaging.

J Mech Behav Biomed Mater

Division of Biomedical Engineering, College of Engineering, University of Saskatchewan, Saskatoon, SK, S7N 5A9, Canada; Department of Mechanical Engineering, College of Engineering, University of Saskatchewan, Saskatoon, SK, S7N 5A9, Canada. Electronic address:

Published: November 2024

AI Article Synopsis

  • - Hydrogel-based scaffolds are popular in soft tissue regeneration for their ability to create a biocompatible and tissue-like environment, but assessing their mechanical properties and microstructure post-implantation poses challenges due to the destructiveness of traditional testing methods.
  • - The study explores the use of synchrotron radiation propagation-based imaging-computed tomography (SR-PBI-CT) as a non-destructive technique for characterizing the mechanical and internal properties of these scaffolds.
  • - Researchers created hydrogel scaffolds with specific biomaterial inks, tested their compressive strength, and simultaneously imaged them under mechanical load to determine their stress-strain behavior and internal microstructure, achieving Young's modulus values between 5-25 kPa.

Article Abstract

Hydrogel-based scaffolds have been widely used in soft tissue regeneration due to their biocompatible and tissue-like environment for maintaining cellular functions and tissue regeneration. Understanding the mechanical properties and internal microstructure of hydrogel-based scaffold, once implanted, is imperative in tissue engineering applications and longitudinal studies. Notably, this has been challenging to date as various conventional characterization methods by, for example, mechanical testing (for mechanical properties) and microscope (for internal microstructure) are destructive as they require removing scaffolds from the implantation site and processing samples for characterization. Synchrotron radiation propagation-based imaging-computed tomography (SR-PBI-CT) is feasible and promising for non-destructive visualizing of hydrogel scaffolds. As inspired, this study aimed to perform a study on the characterization of mechanical properties and microstructure of hydrogel scaffolds based on the SR-PBI-CT. In this study, hydrogel biomaterial inks composed of 3% w/v alginate and 1% w/v gelatin were printed to form scaffolds, with some scaffolds being degraded over 3 days. Both degraded and undegraded scaffolds underwent compressive testing, with the strains being controlled at the preset values; meanwhile stresses within scaffolds were measuring, resulting the stress-strain curves. Concurrently, the scaffolds were also imaged and examined by SR-PBI-CT at Canadian Light Source (CLS). During the imaging process, the scaffolds were mechanically loaded, respectively, with the strains same as the ones in the aforementioned compressive testing, and at each strain, the scaffold was scanned with a pixel size of 13 μm. From the stress-strain curves obtained in the compression testing, the Young's modulus was evaluated to characterize the elastic behavior of scaffolds: with the range between around 5-25 kPa. From the images captured by SR-PBI-CT, the scaffolds microstructures were examined in terms of the strand cross-section area, pore size, and hydrogel volume. Further, from the SR-PBI-CT images, the stress within hydrogel of scaffolds were evaluated, showing the agreement with those obtained from compression testing. These results have illustrated that the mechanical properties and microstructures of scaffolds, ether being degraded or not, can be examined and characterized by the SR-PBI-CT imaging, in a non-destructive manner. This would represent a significant advance for facilitating longitudinal studies on the scaffolds once implanted in-vivo.

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Source
http://dx.doi.org/10.1016/j.jmbbm.2024.106844DOI Listing

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