Abstract
Introduction
The applied heat level and expose time are main issues in certain operations/applications, such as a laser assisted tissue welding, preparation of collagen-based biomaterials (films, implants). Therefore, the precise investigation of these parameters is crucial. The results can serve as a guideline to assess potential effects while maintaining the functionality of the collagen structures.
Methods
Collagen tissues from rat-tail tendon, calfskin, and bones are soaked in buffer solutions, then examined by microscope at different temperature levels.
Results
Increase in temperature reduced the microscopically observed collagen crimp contrast for calfskin and rat-tail tendons but not for bone tissues. The contrast level for rat tail tendon decreased down to 80% of its initial value at 37, 157, and 266 s for 70, 65, and 60 °C, respectively. The decrease in the crimp contrast was about only 25% and 2% at 55 and 50 °C after 2 h, respectively. 50% drop in contrast level was occurred for the skin samples at 16, 90, 110 and 1900 s for 70, 65, and 60 °C, respectively. The bone samples, did not show any significant differences in contrast levels.
Conclusion
The observed denaturation behaviours are in line with Arrhenius Law. This study could be expanded on to other types of tissues at wider temperature ranges to make a guideline for biological/medical processes that radiate heat in order to assess their side effects on collagen and other proteins.
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Acknowledgments
We thank Enes Atas (scientist in Biomedical Engineering Department at Istanbul Medeniyet University) for helping us to prepare bone samples and Ekin Opar (research assistant in Biomedical Engineering Program at Istanbul Technical University) for analysis and discussing the results.
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İrem Deniz Derman, Esat Can Şenel, Onur Ferhanoğlu, İnci Çilesiz, and Murat Kazanci declare that they have no conflicts of interest.
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Derman, İ.D., Şenel, E.C., Ferhanoğlu, O. et al. Effect of Heat Level and Expose Time on Denaturation of Collagen Tissues. Cel. Mol. Bioeng. 14, 113–119 (2021). https://doi.org/10.1007/s12195-020-00653-w
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DOI: https://doi.org/10.1007/s12195-020-00653-w