Plascencia Martinez Damian Francisco, Quiroz Castillo Jesús Manuel, Ospina Orejarena Alida, Pérez Gallardo Alfonso, Méndez Merino Emilio, Trimmer López Gerardo Asael, López Peña Itzel Yanira, Hernández Martínez Diego, López Gastelum Karla Alejandra, Leyva Verduzco Abraham Alejandro, Ledezma Antonio S, Castillo Ortega María Mónica
Departamento de Investigación en Polímeros y Materiales, Universidad de Sonora, Blvd Luis Encinas y Rosales S/N, Colonia Centro ,Hermosillo ,Sonora 83000, México.
Centro de Tecnología de Sigma Alimentos, Autopista al Av. aeropuerto km. 10 Tecnología 302 y 304, Planta PIIT ,Apodaca ,NL 66629, México.
ACS Omega. 2024 Sep 29;9(40):41157-41170. doi: 10.1021/acsomega.4c01016. eCollection 2024 Oct 8.
The preparation of materials with application in the biomedical field needs to attend some characteristics such as biocompatibility, nontoxicity, adequate mechanical properties, and the ability to mimic the extracellular matrix. Scaffolds for use in cell culture were prepared based on gelatin, polylactic acid (PLA), aloe vera mucilage, and tetracycline. Fibers were prepared in single and coaxial configuration and then cross-linked with glutaraldehyde saturated vapor. The fibers were obtained with cylindric morphology and changed to ribbon morphology and porous membranes, similarly to the extracellular matrix, when cross-linked. Membranes prepared by coaxial electrospinning showed core-shell structures when observed by transversal images, which is beneficial for controlled drug release. Characterization techniques such as scanning electron microscopy, thermogravimetric analysis, and Fourier transform infrared spectroscopy demonstrated the cross-linking due to the increase in diameter, formation of imine groups, and improvement of thermal stability. Antibiotic release tests showed that the prevalent release mechanism is diffusion and can be controlled considering the encapsulation effect, when fibers are prepared with a coaxial configuration, increasing the drug release time, making it a suitable material for controlled release. The biological evaluation of the scaffolds was carried out in two cell lines: mammalian adipose stem cells (ASCs), used as a primary cell culture, and Detroit 548 human skin fibroblasts as a dermal cell model. Aloe vera enriched scaffolds showed better activity in contact with both cell lines, exhibiting cell viability values greater than 90% and favorable results in live-dead assays when no damaged cells were observed. Cell proliferation was evaluated using Detroit 548 human skin fibroblast on gelatin-based scaffolds by the staining of the adhered cells; the images showed good confluence and morphology of the cells on the aloe vera and antibiotic loaded membranes for both of the studied configurations. Antibiotic loaded membranes presented antimicrobial activity against , and this behavior increased when aloe vera is included. According to the results, the scaffolds prepared on single configuration enriched with aloe vera and tetracycline could be used in dermal tissue engineering as burn dressings, diabetic foot apposite, and skin substitutes, and the scaffolds prepared with a coaxial configuration are recommended for controlled release systems of antibiotics as treatments for chronic wounds such as diabetic foot and burn healing.
用于生物医学领域的材料制备需要具备一些特性,如生物相容性、无毒性、适当的机械性能以及模拟细胞外基质的能力。基于明胶、聚乳酸(PLA)、芦荟黏液和四环素制备了用于细胞培养的支架。纤维以单轴和同轴结构制备,然后用饱和戊二醛蒸汽交联。纤维呈圆柱形形态,交联后变为带状形态和多孔膜,类似于细胞外基质。通过横向图像观察,同轴静电纺丝制备的膜呈现核壳结构,这有利于药物的控释。扫描电子显微镜、热重分析和傅里叶变换红外光谱等表征技术表明,由于直径增加、亚胺基团的形成以及热稳定性的提高,发生了交联。抗生素释放试验表明,普遍的释放机制是扩散,当纤维以同轴结构制备时,考虑到包封效应可以控制释放,延长药物释放时间,使其成为适合控释的材料。在两种细胞系中对支架进行了生物学评估:用作原代细胞培养的哺乳动物脂肪干细胞(ASC)和作为真皮细胞模型的底特律548人皮肤成纤维细胞。富含芦荟的支架与两种细胞系接触时均表现出更好的活性,细胞活力值大于90%,在活死细胞检测中未观察到受损细胞时结果良好。通过对附着细胞染色,使用底特律548人皮肤成纤维细胞在基于明胶的支架上评估细胞增殖;图像显示,对于两种研究的结构,在富含芦荟和抗生素的膜上细胞具有良好的汇合度和形态。载有抗生素的膜对……具有抗菌活性,当加入芦荟时这种活性增强。根据结果,单轴结构制备的富含芦荟和四环素的支架可用于皮肤组织工程,作为烧伤敷料、糖尿病足敷料和皮肤替代物,而同轴结构制备的支架推荐用于抗生素控释系统,作为糖尿病足和烧伤愈合等慢性伤口的治疗方法。
