Assessment of the Impact of Decellularization Methods on Mechanical Properties of Biocomposites Used as Skin Substitute.

Bożena Gzik-Zroska,Marek Gzik,Arkadiusz Szarek,Kamil Joszko,Jerzy Malachowski,Michał Tomaszewski,Diana Kitala,Marek Ples,Wojciech Wolański,Grzegorz Stradomski,Sławomir Suchoń,Mohsen Akbari,Michał Burkacki

doi:10.3390/ma14174785

Abstract

This work aimed to assess the impact of acellularization and sterilization methods on the mechanical properties of biocomposites used as a skin substitute. On the basis of the statistical analysis, it was ascertained that the values of the Young modulus for the samples before the sterilization process—only in the cases of substances such as: trypsin, 15% glycerol and dispase—changed in a statistically significant way. In the case of dispase, the Young modulus value before the sterilization process amounted to 66.6 MPa, for trypsin this value equalled 33.9 MPa, whereas for 15% glycerol it was 11 MPa. In the case of samples after the completion of the sterilization process, the analysis did not show any statistically significant differences between the obtained results of Young’s modulus depending on the respective reagents applied. It was confirmed that different methods of acellularization and the process of sterilization effect the alteration of mechanical properties of allogeneic skins. In the case of the decellularization method using SDS (Sodium Dodecyl Sulfate), liquid nitrogen and 85% glycerol the highest values of strain were observed. In the authors’ opinion, it is the above-mentioned methods that should be recommended in the process of preparation of skin substitutes.

Highlights

Skin substitutes are an effect of a complex technological process and should be treated as composite-like constructs
The highest mean stress values for the samples before sterilization were observed for the samples subjected to decellularization by means of dispase 11.2 ± 6.9 MPa
In the case of samples subjected to the process of 14, stress of sterilization, the highest mean stress values were observed for three methods of cell removal: SDS and trypsin 6.9 ± 2.6 MPa, 85% glycerol 6.8 ± 5.9 MPa, and trypsin 6.7 ± 4.1 cell noticed removal: in

Summary

Introduction

Skin substitutes are an effect of a complex technological process and should be treated as composite-like constructs They are usually built from a component playing the role of a load-bearing structure as well as different types of cells. The most popular treatment of the defect or loss of skin layers involves the use of biostatic grafts (deprived of living cells) They are often called biological dressings or scaffolds and constitute the above-mentioned load-bearing structure. Despite relatively big—as for mammals—regenerative abilities, there occur injuries which the organism finds impossible to repair and self-regenerate [2,3,4,5] Due to this fact, the replacement of damaged skin fragments is a crucial and often decisive aspect of the treatment [6]

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