Electrospun scaffolds of self-assembling peptides with poly(ethylene oxide) for bone tissue engineering

TL;DR: An overview of the design of ideal biomimetic porous scaffolds for bone tissue engineering is presented, and concepts and techniques including the production of a hierarchical structure on both the macro- and nano-scales, the adjustment of biomechanical properties through structural alignment and chemical components, and the control of the biodegradability of the scaffold and its by-products are discussed.

TL;DR: This review gives an overview of some current aspects of various applications of electrospun fibers, particularly in biomedical fields, how researchers have enhanced electrospin fibers with different methods and attempted to overcome the inherent limitation of electro Spinning by using novel techniques.

TL;DR: The following review has been focused on studies of electrospinning process as the most promising fabrication technique for tissue engineering and drug delivery applications.

TL;DR: In this paper, three process domains and the physical domain of charge interaction are identified as important in electrospinning: (a) creation of charge carriers, (b) creating charge carriers and (c) charge interaction.

TL;DR: The use of self-assembling materials in combination with a bioengineering platform is proposed to assist functional bone regeneration in cases of larger bone defects, including exposed fractures due to trauma and spinal disorders dealing with high loadings, as well as replacement of big bone structures due to tumors.

TL;DR: In this article, regenerated silk fibroin (SF) aqueous solutions were adjusted to a pH of 69 by mimicking the condition in the posterior division of silkworm's gland and rheological behavior of solutions.

TL;DR: Part 1 Cell responses to biomaterials using polymers and ceramics: Biocompatible 3-D scaffolds for tendon tissue engineering using electrospinning and In vitro testing of biomaterial toxicity and biocompatibility.

TL;DR: The present study suggests that hybrid scaffolds made from PEEK cages and SAPS can be useful tools for the regeneration of load-bearing bones by combining the strength of artificial bone with the bone regeneration and bone conduction properties of SAPS.