4.7 Article

Supercritical carbon dioxide decellularization of plant material to generate 3D biocompatible scaffolds

Journal

SCIENTIFIC REPORTS
Volume 11, Issue 1, Pages -

Publisher

NATURE PORTFOLIO
DOI: 10.1038/s41598-021-83250-9

Keywords

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Funding

  1. Center for Applied Nanobioscience and Medicine
  2. Clinical Translational Science graduate program
  3. Valley Research Partnership [PI-4005]
  4. Arizona Biomedical Research Centre [ADHSS17-0000403/45773]
  5. [NNCI-ECCS-1542160]

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This study presents an alternative approach to plant decellularization using supercritical carbon dioxide (scCO(2)) that can effectively preserve plant microarchitecture and enable repopulation with human cells. Comparative analysis with chemically generated scaffolds showed that scCO(2) decellularized spinach leaf scaffolds exhibited similar mechanical properties and element composition but distinct biochemical signatures. Furthermore, human fibroblast cells seeded on the scCO(2) decellularized scaffolds demonstrated attachment and viability after 14 days, indicating excellent biocompatibility. The use of scCO(2) in this process was found to be more efficient, taking only 36 hours compared to the standard chemical approach which takes 170 hours.
The use of plant-based biomaterials for tissue engineering has recently generated interest as plant decellularization produces biocompatible scaffolds which can be repopulated with human cells. The predominant approach for vegetal decellularization remains serial chemical processing. However, this technique is time-consuming and requires harsh compounds which damage the resulting scaffolds. The current study presents an alternative solution using supercritical carbon dioxide (scCO(2)). Protocols testing various solvents were assessed and results found that scCO(2) in combination with 2% peracetic acid decellularized plant material in less than 4 h, while preserving plant microarchitecture and branching vascular network. The biophysical and biochemical cues of the scCO(2) decellularized spinach leaf scaffolds were then compared to chemically generated scaffolds. Data showed that the scaffolds had a similar Young's modulus, suggesting identical stiffness, and revealed that they contained the same elements, yet displayed disparate biochemical signatures as assessed by Fourier-transform infrared spectroscopy (FTIR). Finally, human fibroblast cells seeded on the spinach leaf surface were attached and alive after 14 days, demonstrating the biocompatibility of the scCO(2) decellularized scaffolds. Thus, scCO(2) was found to be an efficient method for plant material decellularization, scaffold structure preservation and recellularization with human cells, while performed in less time (36 h) than the standard chemical approach (170 h).

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