New guide for using mechanical stimulation to improve tissue-engineered cartilage

image: Tissue Engineering brings together scientific and medical experts in the fields of biomedical engineering, material science, molecular and cellular biology, and genetic engineering.

Image: 
Mary Ann Liebert, Inc., publishers

New Rochelle, NY, June 20, 2018--Tissue-engineered articular cartilage (AC) for repairing cartilage damaged by trauma or disease can be made to more closely mimic natural AC if mechanical stimulation of particular magnitude and duration is applied during the development process. A detailed review of the different stimulation techniques used and how to determine optimal loading parameters for improving the mechanical, structural, and cellular properties of AC is published in Tissue Engineering, Part B (Reviews), a peer-reviewed journal from Mary Ann Liebert, Inc., publishers . The article is available free on the Tissue Engineering website until July 20, 2018.

In "A Guide for Using Mechanical Stimulation to Enhance Tissue-Engineered Articular Cartilage Properties ," coauthors Evelia Salinas, Jerry Hu, PhD, and Kyriacos Athanasiou, PhD, University of California, Irvine, provide a comprehensive overview of the significant progress that has been made in the optimization of loading parameters in AC constructs. The researchers have developed a guide to the qualitative and quantitative effects that can be achieved when various loading parameters are used in tissue-engineered AC, including direct compression, hydrostatic pressure, shear, and tensile loading.

"The translation of tissue-engineered products into clinical reality is a main goal for the field. Improvement of existing protocols and SOP development with focus on achieving full implant functionality, as well as validation and GLP/GMP conformity, are key aspects," says Tissue Engineering Part B Editor Katja Schenke-Layland, MSc, PhD, Eberhard Karls University, Tübingen. "This review is an important guide for derivation of functional in vitro-engineered articular cartilage."

Credit: 
Mary Ann Liebert, Inc./Genetic Engineering News