Jorjani Biomedicine Journal

---

Preparation of nano-microfibers from biopolymers (e.g., proteins and polysaccharides) by using electrospinning technology has been considered by researchers due to the formation of fibers or particles at the nano and micrometer scales, high porosity level, adjustable dewatering behavior, and special mechanical behavior. These products can be used in the microencapsulation of bioactive compounds, stabilization of enzymes and smart packaging. In the electrospinning method, a high voltage is used to create a nanofibers-particles. When the electric field overcomes the surface tension of the droplet, a jet exits the polymeric solution and is formed along the collector surface as it stretches toward the collector panel of the nanofiber. Parameters including molecular weight and polymer microstructure characteristics such as electrical conductivity, viscosity, surface tension, and the electrical potential applied by the device, solution flow rate, distance between the tip of the needle and the collector plate and sometimes the material of the collector plate are effective in the formation of electrospun fibers and particles. In this review, we discussed and evaluated the production stages, the strengths and weaknesses of the fibers produced from proteins and polysaccharides, and their functional properties and potentials, especially in food and drug sciences.
 

---

One of the major challenges in the field of tissue engineering is the production of scaffolding in nano-scale. The study of structural-functional connections in pathological and normal tissues with biologically active alternatives or engineered materials has been developed. Extracellular Matrix (ECM) is a suitable environment consisting of gelatin, elastin and collagen types I, II and III, etc., which are provided to cells for wound healing, embryonic development, cell growth and organogenesis, and. They also play a role in transmitting structural integrity and overall strength to tissues. In tissues, ECM manufacturers are structurally 50 to 500 nm in diameter; nanotechnology must be used to create scaffolds or ECM analogues. Recent advances in nanotechnology have led to the development of ECM-engineered analogues in various ways. To date, three self-assembly, phase separation and electrospinning techniques have been developed to activate nanofiber scaffolds. With these advances and the construction of a "biomimetic" environment, engineered tissue or scaffolding is now possible for a variety of tissues. This study will discuss the three existing methods for creating Tissue engineering scaffolds that are able to mimic new tissue, as well as the discovery of materials for use in scaffolding.