Abstract
Each year tissue engineering costs the United States $2 million dollars. Bacterial Cellulose (BC), a hydrogel with a ne ber network, is produced by the bacterium Acetobacter xylinum that can be used as a protective coating. In contrast to other polymers, BC possesses high tensile strength, high water holding capabilities, and high mechanical properties. The purpose of the current study is to determine if individual bers of BC can be functionalized with calcium by applying an electric eld. BC was grown and calcium was deposited simultaneously using Corn Steep Liquor (CSL) media, with the addition of fructose, in channels 4 cm long x 5 mm wide x 2.5 mm deep. The channels contained platinum electrodes supplying an electric eld of 3 to 7.5 volts for 72 hours in the presence of CaCl 2 . BC pellicles formed and were then examined using the Environmental Scanning Electron Microscope (ESEM). Energy-Dispersive X-ray Spectroscopy (EDS) was also used to determine the composition in each sample. Calcium was found deposited on the BC bers at 5.5 volts. Lower voltages, such as 4.0 volts, resulted in no calcium deposition on the bers. The presence of Carboxymethyl Cellulose (CMC) is critical for the calcium deposition. Calcium deposition will occur at 5.5 volts suggesting there may be a speci c electric eld requirement for calcium deposition on BC.
Highlights
Tissue engineering research is a growing field where researchers experiment with more efficient and inexpensive ways to create scaffolds
Allografts are the most frequently chosen bone substitutes because of the availability of tissue and its ability to be customized through manufacturing
Energy-Dispersive X-ray Spectroscopy (EDS) analysis was carried out for the 5.5V sample and small amounts of calcium along with palladium from the coating, and platinum were detected in the sample
Summary
Tissue engineering research is a growing field where researchers experiment with more efficient and inexpensive ways to create scaffolds These scaffolds will repair or replace whole tissues quicker than previous methods. Typical complications include blood loss, nerve injury, infection, hernia fracture, cosmetic defects, and occasional chronic pain at the donor site.[4] Between autografts and allografts, allografts are the most frequently chosen bone substitutes because of the availability of tissue and its ability to be customized through manufacturing. These synthetic bone grafts should be biocompatible, show minimal fibrotic reaction, undergo remodeling, and support new bone formation. By creating a more efficient product to replace bone grafts millions of dollars would be saved worldwide.[3, 5]
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