An In Situ-Gelling Conductive Hydrogel for Potential Use in Neural Tissue Engineering.

IF 3.5 3区 医学 Q3 CELL & TISSUE ENGINEERING Tissue Engineering Part A Pub Date : 2024-12-01 Epub Date: 2024-04-05 DOI:10.1089/ten.TEA.2023.0359
Atefeh Amirabdollahian, Mohammad Moeini
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Abstract

Cerebral cavitation is usual following acute brain injuries, such as stroke and traumatic brain injuries, as well as after tumor resection. Minimally invasive implantation of an injectable scaffold in the cavity is a promising approach for potential regeneration of tissue loss. This study aimed at designing an in situ-gelling conductive hydrogel containing silk fibroin (SF), brain decellularized extracellular matrix (dECM), and carbon nanotubes (CNT) for potential use in brain tissue regeneration. Two percent w/v SF hydrogels with different concentrations of dECM (0.1%, 0.2%, or 0.3% w/v) and CNTs (0.05%, 0.1%, or 0.25% w/v) were fabricated and characterized. It was observed that with the addition of dECM, the porosity decreased, whereas swelling and electrical conductivity tended to increase. The addition of dECM also led to a faster resorption rate, but no significant change in compressive modulus. Addition of CNTs, on the other hand, led to a denser, stronger, and more regular porous structure, higher swelling ratio, faster gelation time, slower degradation rate, and a significant increase in electrical conductivity. dECM and CNTs combined together resulted in superior porosity, swelling, resorption rate, mechanical properties, and electrical conductivity compared with SF scaffolds containing only dECM or CNTs. Hydrogel samples containing 2% SF, 0.3% dECM, and 0.1% CNTs had a high porosity (58.9%), low swelling ratio (15.9%), high conductivity (2.35 × 10-4 S/m), and moderate degradation rate (37.3% after 21 days), appropriate for neural tissue engineering applications. Cell evaluation studies also showed that the hydrogel systems support the cell adhesion and growth, with no sign of significant cytotoxicity. Impact statement Tissue loss and formation of a fluid-filled cavity following stroke, traumatic brain injury, or brain tumor resection lead to sensorimotor and/or cognitive deficits. The lack of a healthy extracellular matrix in the cavity avoids the endogenous cell migration and axonal sprouting and may also worsen the secondary injuries to peri-lesional tissue. Due to the brain anatomy, simple implantation of tissue engineering scaffolds to the injured site is not possible in many cases. Therefore, the development of injectable scaffolds that support neural growth and differentiation is crucial for tissue repair or limiting the expansion of damage region.

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一种可用于神经组织工程的原位胶凝导电水凝胶。
脑空洞症常见于急性脑损伤(如中风和脑外伤)以及肿瘤切除术后。在空腔内微创植入可注射支架是一种很有前景的方法,可用于潜在的组织损失再生。本研究旨在设计一种原位胶凝导电水凝胶,其中含有丝纤维蛋白(SF)、脑脱细胞 ECM(dECM)和碳纳米管(CNT),有望用于脑组织再生。制备并表征了含有不同浓度 dECM(0.1%、0.2% 或 0.3% w/v)和碳纳米管(0.05%、0.1% 或 0.25% w/v)的 2% w/v SF 水凝胶。结果表明,添加 dECM 后,孔隙率降低,而膨胀率和导电率呈上升趋势。添加 dECM 还导致吸收速度加快,但压缩模量没有显著变化。另一方面,添加碳纳米管会使多孔结构更致密、更坚固、更规整,溶胀率更高,凝胶时间更快,降解速度更慢,导电率显著增加。与仅含 dECM 或碳纳米管的 SF 支架相比,dECM 和碳纳米管结合在一起会产生更高的孔隙率、溶胀率、吸收率、机械性能和导电率。含有 2% SF、0.3% dECM 和 0.1% CNT 的水凝胶样品具有高孔隙率(58.9%)、低膨胀率(15.9%)、高导电率(2.35×10-4 S/m)和适度降解率(21 天后降解率为 37.3%),适合神经组织工程应用。细胞评估研究也表明,水凝胶系统支持细胞粘附和生长,没有明显的细胞毒性迹象。
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来源期刊
Tissue Engineering Part A
Tissue Engineering Part A Chemical Engineering-Bioengineering
CiteScore
9.20
自引率
2.40%
发文量
163
审稿时长
3 months
期刊介绍: Tissue Engineering is the preeminent, biomedical journal advancing the field with cutting-edge research and applications that repair or regenerate portions or whole tissues. This multidisciplinary journal brings together the principles of engineering and life sciences in the creation of artificial tissues and regenerative medicine. Tissue Engineering is divided into three parts, providing a central forum for groundbreaking scientific research and developments of clinical applications from leading experts in the field that will enable the functional replacement of tissues.
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