Team:UCL/Project/About

The Problem: Azo Dyes in the Environment

Since their discovery in ? azo dyes have become one of the most popular forms of synthetic colourant used in the industrial manufacture of a wide range of products such as clothing, upholstery, cosmetics, tattoo ink and many more. Although azo-dyes are widely regarded as safe and stable forms of synthetic colourants some of them can take on dangerous properties after they are broken down in the guts of organisms. In industry, leftover dye effluent is often not properly disposed of, or removed, during water treatment, which results in the accumulation of azo dyes in water bodies. At this point that these dyes are ingested by aquatic organisms and broken down into products that have been found to be mutagenic and carcinogenic. Despite such toxicity, little to no effort has been made to dispose of these leftover azo dyes more responsibly.

The Solution: Goodbye AzoDyes, UCL iGEM Team 2014

Our iGEM project developed a process for controllably degrading and detoxifying the excess azo-dye effluent at the source - the textile factories - by filtering the different toxic breakdown products elsewhere, before they ever reach the water systems. Our aim was to then convert these products into innoculous, and potentially useful, chemicals that can be used in other processes. We achieved this goal by introducing the genes for three enzymes related to the degradation of these dyes: azoreductase, laccase, and lignin peroxidase into a host E.coli cell to create an enhanced azo-dye decolourising organism.

Implementation in Industry

In the textile industry today, annual production of dyestuff amounts to millions of tons globally. Azo dyes represent two thirds of this value, a majority of which find their way to wastewater. Our idea is to conceive an integrated end-of-pipe method for detoxifying effluent streams of dye factories. The goal is to achieve a two-stage regimen in sequence to ensure optimal conditions for the degradation of azo dyes within a batch bioreactor system. This would be an attractive and effective approach to dealing with azo dye contamination of the environment. As a financial incentive, we are also looking at maximizing the profitability of various potential breakdown products. As a lucrative continuous-process alternative, we are investigating the application of microbial fuel cell technology to an aerobic bioreactor system, for simultaneously detoxifying azo dyes and generating electricity. Considering the potential for scalability, this method would present various economic and environmental advantages for industries that generate large amounts of dyestuff. This could also be spinned to become a modular bioprocess method for wastewater treatment of other toxic, normally recalcitrant chemicals.