Possibilities of using allogeneic mesenchymal stem cells and wound dressings based on aliphatic copolyamide in microautodermoplasty
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| 1. | Title | Title of document | Possibilities of using allogeneic mesenchymal stem cells and wound dressings based on aliphatic copolyamide in microautodermoplasty |
| 2. | Creator | Author's name, affiliation, country | Vasily A. Gordienko; Saint Petersburg State Pediatric Medical University; Russian Federation |
| 2. | Creator | Author's name, affiliation, country | Evgenii V. Zinoviev; Saint Petersburg State Pediatric Medical University; Saint Petersburg I.I. Dzhanelidze Research Institute of Emergency Medicine; Russian Federation |
| 2. | Creator | Author's name, affiliation, country | Denis V. Kostyakov; Saint Petersburg I.I. Dzhanelidze Research Institute of Emergency Medicine; Russian Federation |
| 2. | Creator | Author's name, affiliation, country | Marat S. Asadulaev; H. Turner National Medical Research Center for Сhildren’s Orthopedics and Trauma Surgery; Russian Federation |
| 2. | Creator | Author's name, affiliation, country | Anton S. Shabunin; H. Turner National Medical Research Center for Сhildren’s Orthopedics and Trauma Surgery; Peter the Great Saint Petersburg Polytechnic University; Russian Federation |
| 2. | Creator | Author's name, affiliation, country | Vladimir E. Yudin; Peter the Great Saint Petersburg Polytechnic University; Russian Federation |
| 2. | Creator | Author's name, affiliation, country | Nataliya V. Smirnova; Peter the Great Saint Petersburg Polytechnic University; Institute of Macromolecular Compounds of the Russian Academy of Sciences; Russian Federation |
| 2. | Creator | Author's name, affiliation, country | Anna V. Radeeva; Saint Petersburg State Pediatric Medical University; Russian Federation |
| 2. | Creator | Author's name, affiliation, country | Moisei B. Paneiakh; Saint Petersburg State Pediatric Medical University; Russian Federation |
| 3. | Subject | Discipline(s) | |
| 3. | Subject | Keyword(s) | wound; burn; extensive wound defects; microautodermoplasty; wound dressings; aliphatic copolyamide; stem cells |
| 4. | Description | Abstract | Background. The treatment of victims with wound defects is an urgent problem of clinical medicine that doctors of various specialties, mainly surgeons and traumatologists, must face. Regardless of the etiology of the traumatic agent, the wound process is always subjected to fundamental pathophysiological processes. Despite the advances made by medical science in the local treatment of wounds (cell technology, modern wound coverings, and others), surgical procedures remain the main methods, and the search for new techniques to optimize reparative regeneration continues. This ongoing search indicates the absence of a universal algorithm for treating such defects. This lack of a universal treatment algorithm is of particular importance for assisting victims with extensive defects, which often leads to a shortage of donor resources. Aim. The aim of this study was to increase the efficiency of microautodermoplasty due to the use of allogeneic mesenchymal stem cells and wound dressings based on aliphatic copolyamide. Materials and methods. This paper presents the results of an experimental study involving 50 rats. All animals were divided into groups considering the choice of the method of the local treatment. The experimental wound was modeled according to its original technique. The evaluation of the effectiveness of the analyzed methods was performed using planimetric and histological research methods, and by calculating the healing index. Results. The most effective methods for treating experimental wounds using microautodermoplasty (MADP) are wound dressings based on aliphatic copolyamide (CoPA) and adipogenic mesenchymal stem cells (AMSC). By 28 days of treatment after performing MADP + CoPA wound dressings + AMSC, it was possible to reduce the defect area by 16 times compared with the control, and the healing index was the maximum value among all methods — 12.5 units. The high regenerative potential was also confirmed by the results of the histological examination. The worst results were found in the MADP group with AMSK that did not cover the wounds with skin or wound dressing. Conclusion. The introduction of the analyzed methods into clinical practice will improve the results of treatment of patients with wound defects of various etiologies. |
| 5. | Publisher | Organizing agency, location | Eco-Vector |
| 6. | Contributor | Sponsor(s) |
Russian Science Foundation (197330003) |
| 7. | Date | (DD-MM-YYYY) | 01.07.2020 |
| 8. | Type | Status & genre | Peer-reviewed Article |
| 8. | Type | Type | Research Article |
| 9. | Format | File format | |
| 10. | Identifier | Uniform Resource Identifier | https://ogarev-online.ru/turner/article/view/25751 |
| 10. | Identifier | Digital Object Identifier (DOI) | 10.17816/PTORS25751 |
| 10. | Identifier | Digital Object Identifier (DOI) (PDF (Rus)) | 10.17816/PTORS25751-23290 |
| 10. | Identifier | Digital Object Identifier (DOI) (PDF (Eng)) | 10.17816/PTORS25751-31565 |
| 10. | Identifier | Digital Object Identifier (DOI) (PDF (简体中)) | 10.17816/PTORS25751-28338 |
| 11. | Source | Title; vol., no. (year) | Pediatric Traumatology, Orthopaedics and Reconstructive Surgery; Vol 8, No 2 (2020) |
| 12. | Language | English=en | ru |
| 13. | Relation | Supp. Files |
Fig. 1. The results of measuring the area of wounds in the analyzed groups of animals during the follow-up period: MADP — microautodermoplasty; CPA — aliphatic copolyamide; AMSC — adipogenic mesenchymal stem cells (530KB) doi: 10.17816/PTORS25751-25924 Fig. 2. The results of assessing the dynamics of the wound healing index in the analyzed groups of animals during the follow-up period: MADP — microautodermoplasty; CPA — aliphatic copolyamide; AMSC — adipogenic mesenchymal stem cells (508KB) doi: 10.17816/PTORS25751-25925 Fig. 3. Comparison of the dynamics of the healing index (median values) in the analyzed groups of animals: MADP — microautodermoplasty; CPA — aliphatic copolyamide; AMSC — adipogenic mesenchymal stem cells (114KB) doi: 10.17816/PTORS25751-25926 Fig. 4. A slice of the new skin on day 7 after microautodermoplasty (coated with aliphatic copolyamide) and the administration of adipogenic mesenchymal stem cells. Thinning of the epidermis and the pseudocyst formation process. Hematoxylin and eosin staining, magnification by 100× (271KB) doi: 10.17816/PTORS25751-25927 Fig. 5. A slice of the new skin on day 21 after microautodermoplasty (coated with aliphatic copolyamide) and the administration of adipogenic mesenchymal stem cells. Deposition of calcium salts surrounded by giant multinucleated cells. Hematoxylin and eosin staining, magnification by 100× (197KB) doi: 10.17816/PTORS25751-25929 Fig. 6. A slice of the new skin on day 28 after microautodermoplasty (coated with an aliphatic copolyamide) and the administration of adipogenic mesenchymal stem cells. Giant cell granuloma with deposition of calcium salts. Hematoxylin and eosin staining, magnification by 100× (328KB) doi: 10.17816/PTORS25751-25930 Fig. 7. A slice of the new skin on day 28 after microautodermoplasty (coated with an aliphatic copolyamide) and the administration of adipogenic mesenchymal stem cells. Thinning, dystrophic changes in the epidermis, active horny pseudocyst. Hematoxylin and eosin stain, magnification by 400× (222KB) doi: 10.17816/PTORS25751-25931 |
| 14. | Coverage | Geo-spatial location, chronological period, research sample (gender, age, etc.) | |
| 15. | Rights | Copyright and permissions |
Copyright (c) 2020 Gordienko V.A., Zinoviev E.V., Kostyakov D.V., Asadulaev M.S., Shabunin A.S., Yudin V.E., Smirnova N.V., Radeeva A.V., Paneiakh M.B. This work is licensed under a Creative Commons Attribution 4.0 International License. |