Shafiee Akram, Ahmadi Hanie, Taheri Behnaz, Hosseinzadeh Simzar, Fatahi Yousef, Soleimani Masoud, Atyabi Fatemeh, Dinarvand Rassoul
Department of Pharmaceutics, Faculty of Pharmacy, Tehran University of Medical Sciences, Tehran, Iran.
Nanotechnology Research Center, Faculty of Pharmacy, Tehran University of Medical Sciences, Tehran, Iran.
Avicenna J Med Biotechnol. 2020 Oct-Dec;12(4):203-220.
Cellular transplantation, due to the low regenerative capacity of the Central Nervous System (CNS), is one of the promising strategies in the treatment of neurodegenerative diseases. The design and application of scaffolds mimicking the CNS extracellular matrix features (biochemical, bioelectrical, and biomechanical), which affect the cellular fate, are important to achieve proper efficiency in cell survival, proliferation, and differentiation as well as integration with the surrounding tissue. Different studies on natural materials demonstrated that hydrogels made from natural materials mimic the extracellular matrix and supply microenvironment for cell adhesion and proliferation. The design and development of cellular microstructures suitable for neural tissue engineering purposes require a comprehensive knowledge of neuroscience, cell biology, nanotechnology, polymers, mechanobiology, and biochemistry. In this review, an attempt was made to investigate this multidisciplinary field and its multifactorial effects on the CNS microenvironment. Many strategies have been used to simulate extrinsic cues, which can improve cellular behavior toward neural lineage. In this study, parallel and align, soft and injectable, conductive, and bioprinting scaffolds were reviewed which have indicated some successes in the field. Among different systems, three-Dimensional (3D) bioprinting is a powerful, highly modifiable, and highly precise strategy, which has a high architectural similarity to tissue structure and is able to construct controllable tissue models. 3D bioprinting scaffolds induce cell attachment, proliferation, and differentiation and promote the diffusion of nutrients. This method provides exceptional versatility in cell positioning that is very suitable for the complex Extracellular Matrix (ECM) of the nervous system.
由于中枢神经系统(CNS)的再生能力较低,细胞移植是治疗神经退行性疾病的一种有前景的策略。模仿中枢神经系统细胞外基质特征(生物化学、生物电和生物力学)的支架的设计和应用对实现细胞存活、增殖、分化以及与周围组织整合的适当效率很重要,这些特征会影响细胞命运。对天然材料的不同研究表明,由天然材料制成的水凝胶模仿细胞外基质并为细胞黏附和增殖提供微环境。设计和开发适用于神经组织工程目的的细胞微结构需要全面了解神经科学、细胞生物学、纳米技术、聚合物、机械生物学和生物化学。在本综述中,我们试图研究这个多学科领域及其对中枢神经系统微环境的多因素影响。已经使用了许多策略来模拟外在线索,这可以改善细胞向神经谱系的行为。在本研究中,我们综述了平行排列、柔软可注射、导电和生物打印支架,这些支架在该领域已取得了一些成功。在不同的系统中,三维(3D)生物打印是一种强大、高度可修改且高度精确的策略,它与组织结构具有高度的结构相似性,并且能够构建可控的组织模型。3D生物打印支架可诱导细胞黏附、增殖和分化,并促进营养物质的扩散。这种方法在细胞定位方面具有出色的通用性,非常适合神经系统复杂的细胞外基质(ECM)。
