Research progress on skin preservation and cryoinjury in burn surgery

doi:10.3877/cma.j.issn.1673-9450.2023.02.001

Abstract

Abstract:

Allogeneic skin is the preferred wound covering for the treatment of patients with extensive deep burns. The quick-frozen vitrified skin preserves the activity of the skin, and the high-quality skin storage provides a guarantee for the clinical treatment in burn surgery. The development of skin bank and the research progress on cryoinjury mechanism and cryoprotectant will improve the scale and quality of skin storage.

Key words: Burns, Allogeneic skin, Skin preservation, Cryoinjury

Dongjie Li, Xiaoming Jia. Research progress on skin preservation and cryoinjury in burn surgery[J]. Chinese Journal of Injury Repair and Wound Healing(Electronic Edition), 2023, 18(02): 93-97.

/ / Recommend

Add to citation manager EndNote|Ris|BibTeX

URL: https://zhssyxfzz.cma-cmc.com.cn/EN/10.3877/cma.j.issn.1673-9450.2023.02.001

https://zhssyxfzz.cma-cmc.com.cn/EN/Y2023/V18/I02/93

References 35

[1]	Łabus W, Kitala D, Szapski M, et al. Tissue Engineering in Skin Substitute[J]. Adv Exp Med Biol, 2021, 1345: 193-208.
[2]	Goodarzi P, Falahzadeh K, Nematizadeh M, et al. Tissue Engineered Skin Substitutes[J]. Adv Exp Med Biol, 2018, 1107: 143-188.
[3]	蔡建华，申传安，孙天骏，等. 新鲜异体头皮联合自体微粒皮修复大面积深度烧伤患者四肢创面的方法建立及疗效观察[J]. 中华烧伤杂志，2019, 35(4): 253-260.
[4]	申传安．异体皮在烧伤外科的应用[J]. 中华烧伤杂志，2019, 35(4): 243-247.
[5]	Gao G, Li W, Chen X, et al. Comparing the Curative Efficacy of Different Skin Grafting Methods for Third-Degree Burn Wounds[J]. Med Sci Monit, 2017, 23: 2668-2673.
[6]	Shang F, Hou Q. Effects of allogenic acellular dermal matrix combined with autologous razor-thin graft on hand appearance and function of patients with extensive burn combined with deep hand burn[J]. Int Wound J, 2021, 18(3): 279-286.
[7]	Nita M, Pliszczynski J, Kowalewski C, et al. New treatment of wound healing with allogenic acellular human skin graft: preclinical assessment and in vitro study[J]. Transplant Proc, 2020, 52(7): 2204-2207.
[8]	Mansour N, Karimizade A, Enderami E, et al. The effect of source animal age, decellularization protocol, and sterilization method on bovine acellular dermal matrix as a scaffold for wound healing and skin regeneration[J]. Artif Organs, 2023，47(2)：302-316.
[9]	Patel S, Ziai K, Lighthall G, et al. Biologics and acellular dermal matrices in head and neck reconstruction: a comprehensive review[J]. Am J Otolaryngol, 2022, 43(1): 103233.
[10]	贾晓明. 异种(体)生物材料与创面修复[J/CD]．中华损伤与修复杂志(电子版)，2020，15(5)：341-346.
[11]	张军，王凌峰，巴特，等．羊皮作为微粒皮的覆盖物在大面积烧伤治疗中的应用[J]．包头医学院学报，2008，(1)：79-80.
[12]	王志刚，胡启翔，刘韬，等．新鲜刃厚猪皮在微粒皮移植中的应用体会[J]．内蒙古医学杂志，2010，42(4)：487-488.
[13]	Leon-Villapalos J, Eldardiri M, Dziewulski P. The use of human deceased donor skin allograft in burn care[J]. Cell Tissue Bank，2010，11(1)：99-104.
[14]	Carrel A. The preservation of tissues and its applications in surgery[J]. Clin Orthop Relat Res, 1992，(278)：2-8.
[15]	Matthews DN. Storage of skin for autogenous grafts[J]. Lancet, 1945, 245(6356)：775-778.
[16]	Hanks JH, Wallace RE. Relation of oxygen and temperature in the preservation of tissues by refrigeration[J]. Proc Soc Exp Biol Med, 1949，71(2)：196-200.
[17]	May SR, Wainwright JF. Optimum warming rates to maintain glucose metabolism in porcine skin cryopreserved by slow cooling[J]. Cryobiology，1985，22(2)：196-202.
[18]	Zhu ZM, Jia XM, Chai JK，et al.Clinical application of skin stored by vitrification[J]. Cryobiology，1995，32(6)：572-573.
[19]	Gzik-Zroska B, Joszko K, Wolański W, et al. Assessment of the Impact of decellularization methods on mechanical properties of biocomposites used as skin substitute[J]. Materials (Basel)，2021，14(17)：4785.
[20]	Pirayesh A, Hoeksema H, Richters C, et al. Glyaderm(®) dermal substitute: clinical application and long-term results in 55 patients[J]. Burns，2015，41(1)：132-144.
[21]	Cinamon U, Eldad A, Chaouat M，et al. A simplified testing system to evaluate performance after transplantation of human skin preserved in glycerol or in liquid nitrogen[J]. J Burn Care Rehabil, 1993，14(4)：435-439.
[22]	Pianigiani E, Ierardi F, Cherubini Di Simplicio F, et al. Skin bank organization[J]. Clin Dermatol，2005，23(4)：353-356.
[23]	Annaratone L, De Palma G, Bonizzi G, et al. Basic principles of biobanking: from biological samples to precision medicine for patients[J]. Virchows Arch, 2021，479(2)：233-246.
[24]	Cahane M, van Baare J. European association of tissue banks[J]. Dev Ophthalmol，2009，43：131-135.
[25]	BalaYadav R, Pathak DP, Varshney R, et al. Design and optimization of a novel herbosomal-loaded PEG-poloxamer topical formulation for the treatment of cold injuries: a quality-by-design approach[J]. Drug Deliv Transl Res，2022，12(11)：2793-2823.
[26]	Zhang N, Yu X, Li W, et al. Extracellular vesicles derived from adipose-derived stem cells facilitate frostbite wound healing by regulating SOCS3 expression[J]. Curr Stem Cell Res Ther, 2022，10.2174/1574888X17666220715094504.
[27]	Gupta A, Reshma GB, Singh P, et al. A Combination of synthetic molecules acts as antifreeze for the protection of skin against cold-induced injuries[J]. ACS Appl Bio Mater, 2022，5(1)：252-264.
[28]	Sivagurunathan S, Vahabikashi A, Yang H, et al. Expression of vimentin alters cell mechanics, cell-cell adhesion, and gene expression profiles suggesting the induction of a hybrid EMT in human mammary epithelial cells[J]. Front Cell Dev Biol，2022，10：929495.
[29]	Pan X, Wang Q, Ning D, et al. Ultraflexible self-healing guar gum-glycerol hydrogel with injectable, antifreeze, and strain-sensitive properties[J]. ACS Biomater Sci Eng, 2018，4(9)：3397-3404.
[30]	Yang Y, Sun H, Shi C, et al. Self-healing hydrogel with multiple adhesion as sensors for winter sports[J]. J Colloid Interface Sci, 2023，629(Pt A)：1021-1031.
[31]	Khan MS, Ibrahim SM, Adamu AA, et al. Pre-grafting histological studies of skin grafts cryopreserved in α helix antarctic yeast oriented antifreeze peptide (Afp1m)[J]. Cryobiology，2020，92：26-33.
[32]	Kratochvílová I, Golan M, Pomeisl K, et al. Theoretical and experimental study of the antifreeze protein AFP752, trehalose and dimethyl sulfoxide cryoprotection mechanism: correlation with cryopreserved cell viability[J]. RSC Adv，2017，7(1)：352-360.
[33]	Heisig M, Mattessich S, Rembisz A, et al. Frostbite protection in mice expressing an antifreeze glycoprotein[J]. PLoS One, 2015，10(2)：e0116562.
[34]	李东杰，贾晓明，杨毅，等．海藻糖对低温储存皮肤组织桥粒芯糖蛋白表达及皮肤活力影响的实验研究[J]. 感染、炎症、修复，2014，15(2)：88-90.
[35]	贾晓明，马彩虹，于瑜，等．海藻糖对低温储存皮肤β1integrin及活力的影响[J]．军医进修学院学报，2008，29(3)：206-208.

Please choose a citation manager

Content to export