Gum based 3D composite scaffolds for bone tissue engineering applications.

The increase in population, greater life expectancy, and lifestyle choices have caused a drastic increase in the number of bone diseases such as bone tumours, osteoarthritis and bone fractures. This results in the dire need for treatment options such as suitable bone grafts that can be easily fabricated, and are economical. In this study, fabricated composite scaffolds are made from polysaccharide biopolymers, namely gellan and guar gum, and hydroxyapatite by freeze drying method. The developed scaffolds of optimum concentration showed a maximum percentage degradation of 13.7% only until 21 days in phosphate buffered saline solution, and minimum swelling capacity. The mechanically stable scaffolds (compressive strength equivalent to cancellous bone region, ˜3-30 MPa) amongst them were then subjected to characterization tests-scanning electron microscopy, fourier transform infrared spectroscopy, X-ray diffraction, swelling ratio percentage determination, degradation profile study and water vapour transmission study. The cytotoxic evaluation of the optimised scaffolds was performed using MTT assay with murine fibroblast (L929) cells and osteosarcoma (MG63) cells. It was found that the scaffolds were non-cytotoxic and additionally, the cells had proliferated well within the scaffolds, which was confirmed by MTT assay at 1, 4 and 7 days after cell seeding onto the scaffolds.

Biomaterials and cells for neural tissue engineering: Current choices.

The treatment of nerve injuries has taken a new dimension with the development of tissue engineering techniques. Prior to tissue engineering, suturing and surgery were the only options for effective treatment. With the advent of tissue engineering, it is now possible to design a scaffold that matches the exact biological and mechanical properties of the tissue. This has led to substantial reduction in the complications posed by surgeries and suturing to the patients. New synthetic and natural polymers are being applied to test their efficiency in generating an ideal scaffold. Along with these, cells and growth factors are also being incorporated to increase the efficiency of a scaffold. Efforts are being made to devise a scaffold that is biodegradable, biocompatible, conducting and immunologically inert. The ultimate goal is to exactly mimic the extracellular matrix in our body, and to elicit a combination of biochemical, topographical and electrical cues via various polymers, cells and growth factors, using which nerve regeneration can efficiently occur.