Cryogenically structured gelatin-based hydrogel as a resorbable macroporous matrix for biomedical technologies

A. Grigoriev, Y. Basok, A. Kirillova, V. A. Surguchenko, N. Shmerko, V. K. Kulakova, R. Ivanov, V. Lozinsky, A. Subbot, V. Sevastianov
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Abstract

Objective: to investigate the biological properties of a matrix made of cryogenically structured hydrogel in the form of a macroporous gelatin sponge, as well as the possibility of creating cell-engineered constructs (CECs) on its basis. Materials and methods. The main components of the cryogenically structured hydrogel were gelatin (type A) obtained from porcine skin collagen, N-(3-dimethylaminopropyl)-N’-ethylcarbodiimide, (EDC) and urea (all from Sigma-Aldrich, USA). Surface morphology was examined using scanning electron microscopy (SEM). The degree of swelling in water of the samples was determined by gravimetric method. Cytotoxicity was studied on NIH3T3, a fibroblast cell line isolated from a mouse, and on human adipose-derived mesenchymal stem/stromal cells (hAMSCs) using IncuCyte ZOOM (EssenBioscience, USA). The metabolic activity of hAMSCs was assessed using PrestoBlue™ reagents (Invitrogen™, USA). To create CECs, we used hAMSCs, human hepatocellular carcinoma cell line HepG2 or human umbilical vein endothelial cell lines EA.hy926. Albumin content in the culture medium was determined by enzyme immunoassay. Ammonia metabolism rate was assessed after 90 minutes of incubation with 1 mM ammonium chloride (Sigma-Aldrich, USA) diluted in a culture medium on day 15 of the experiment. Results. Obtaining a cryogenically structured hydrogel scaffold in the form of macroporous gelatin sponge included freezing an aqueous solution of a gelatin+urea mixture, removal of polycrystals of frozen solvent by lyophilization, extraction of urea with ethanol and treatment of the cryostructurate with an ethanol solution of EDC. Scanning electron microscopy identified three types of pores on the carrier surface: large (109 ± 17 μm), medium (39 ± 10 μm), and small (16 ± 6 μm). The degree of swelling in water of the matrix samples was 3.8 ± 0.2 g H2O per 1 g of dry polymer. The macroporous gelatin sponge as a part of CEC was found to have the ability to support adhesion and proliferation of hAMSCs, EA.hy926 and HepG2 for 28, 15 and 9 days, respectively. Albumin secretion and ammonia metabolism when HepG2 cells were cultured on the gelatin sponge were detected. Conclusion. The use of a matrix made from macroporous cryogenically structured gelatin-based hydrogel for tissue engineering products is shown to be promising using a cell-engineered liver construct as a case.
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低温结构明胶基水凝胶作为生物医学技术的可吸收大孔基质
目的:研究以大孔明胶海绵形式制备的低温结构水凝胶基质的生物学特性,以及在此基础上构建细胞工程构建物(CECs)的可能性。材料和方法。低温结构水凝胶的主要成分是明胶(A型),从猪皮胶原蛋白中提取,N-(3-二甲氨基丙基)-N ' -乙基碳二亚胺(EDC)和尿素(均来自Sigma-Aldrich,美国)。用扫描电子显微镜(SEM)观察表面形貌。用重量法测定试样在水中的溶胀程度。使用IncuCyte ZOOM (EssenBioscience, USA)研究了从小鼠分离的成纤维细胞系NIH3T3和人脂肪源性间充质干细胞/基质细胞(hAMSCs)的细胞毒性。使用PrestoBlue™试剂(Invitrogen™,USA)评估hAMSCs的代谢活性。我们使用hAMSCs、人肝癌细胞系HepG2或人脐静脉内皮细胞系EA.hy926制备CECs。用酶免疫法测定培养基中白蛋白的含量。实验第15天,在培养基中稀释1 mM氯化铵(Sigma-Aldrich, USA),培养90分钟后评估氨代谢率。结果。以大孔明胶海绵的形式获得低温结构的水凝胶支架,包括冷冻明胶+尿素混合物的水溶液,通过冻干去除冷冻溶剂的多晶,用乙醇提取尿素,并用EDC的乙醇溶液处理冷冻结构。通过扫描电镜观察发现,载体表面存在大孔(109±17 μm)、中孔(39±10 μm)和小孔(16±6 μm)三种孔隙类型。基质样品在水中的溶胀度为每1 g干聚合物3.8±0.2 g H2O。大孔明胶海绵作为CEC的一部分,对hAMSCs、EA.hy926和HepG2分别具有28、15和9天的粘附和增殖能力。检测HepG2细胞在明胶海绵上培养时的白蛋白分泌和氨代谢情况。结论。使用由大孔低温结构明胶基水凝胶制成的基质用于组织工程产品被证明是有前途的,以细胞工程肝脏结构为例。
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