Biochemical and Biomedical Engineering

The Department leads a multi-disciplinary research group that is developing methods of growing human cells and tissues outside the body in order to repair or replace damaged tissues. Following implantation, the new tissues should become integrated into the human body and carry out their natural function.

Our research is focused on the regeneration of cartilage, bone and blood vessels, through cultivating the composite cells on both natural and synthetic polymers.

The reconstitution of complex three-dimensional tissue structures is carried out in purpose-designed bioreactor systems. The bioreactor environment allows for careful control of the environmental conditions to optimise the growth of each cell type and its position in the overall structure. Controlling the growth and proliferation of the cells should lead to enhanced tissue properties, and thus deliver the required performance when integrated into the surrounding tissue.

Self-assembling biological structures and polymers that can respond to their environment provide a wide range of interesting opportunities.

We are working on the development of "smart" biological membranes that can interact with their environment. These may be used as coatings for therapeutic agents which can be inserted into the body, and can release a drug or other active agent in response to the state of the patient: for example, by monitoring blood sugar levels and releasing a controlled flow of insulin in response.

A second use for these materials is as self-repairing biocompatible surfaces for coating replacement joints, other prosthetics and medical devices used in invasive treatments.

Smart polymer systems may also be used as fabrics for the production of clothing that responds to the state of the person wearing it. This has applications in sport, medicine and survival in extreme environments.

The Department is exploring the application of supercritical fluids to produce defined coatings on pharmaceutical products. The aim is to produce a "clean technology" process that could replace existing processes in the pharmaceutical industries that currently use solvents, both chlorinated and non-chlorinated, which are harmful to the environment.

The recovery of the products of fermentation and biotransformation processes is being explored in a number of application areas.

Functionalised fluid polymers based on inorganic polymers are being developed and assessed for use as supported liquid membranes for selective separation and extraction. Affinity interactions, based on a ligand tentacle approach, are being exploited to develop an alternative to conventional chromatography resins.

The work covers two aspects of design and development: synthesis and characterisation of polymer supported ligands, and synthesis of tentacle resins. We have extended this research into the separation of different cell types. These include:

• Separation of malignant from healthy cells
• Isolation of specific mutants during strain development
• Selective removal of contaminants during extended fermentor operation.

Producing therapeutic quantities of substances such as human growth hormone and insulin can be time-consuming and expensive because recombinant micro-organisms generally produce proteins which are inactive.

Activity can be regained through a series of steps known as protein refolding, but it is a slow and low-yielding process. We have recently explored the use of mathematical models to optimise refolding reactor operation, reversed micelles, use of the chaperones for in vitro refolding, and the use of hollow-fibre ultrafiltration membranes to minimise protein aggregation.

The use of gel filtration matrices to carry out refolding has proved particularly successful. This technique allows the protein to be refolded at high concentration, minimises aggregation and purifies the product in a single operation.

Organisms have evolved to live in almost every environment on Earth, even the most extreme, such as hot sulphur springs, volcanic vents and the salt-laden Dead Sea.

These extremophiles open up new opportunities for the exploitation of living organisms and their components to create industrial products and processes, with the clear advantage of clean, efficient and safe technology.

Most enzymes from mesophilic (or "conventional") organisms will denature and lose their biological activity above 45°C, at pH values outside the range 5 to 8, or in non-aqueous solvents. Extremophiles, which are generally micro-organisms, have adapted to live outside these confines. The cells and their constituents are extremely stable, and offer considerable biotechnological potential.

We are also exploring the potential for using extremophile organisms in the treatment of industrial effluents.

Many effluents resulting from the synthesis of industrial chemicals are not treatable by conventional biological methods, and they are currently treated using expensive and environmentally questionable technologies such as incineration.

The ability of extremophile organisms to survive in "difficult" environments could be exploited to develop new biological solutions for these problems.

We are working on techniques for the hybridisation of organisms to give them the ability to handle wastes containing mixtures of compounds that in combination pose particular challenges. We are also developing novel membrane bioreactors for accelerated culture evolution. 

Our people

• Dr Tom Arnot
• Dr Mike Bird
• Professor Julian Chaudhuri (group director)
• Dr Chris Chuck
• Dr Mirella Di Lorenzo
• Dr Marianne Ellis
• Dr Tim Mays
• Dr Semali Perera
• Dr Pawel Plucinski 
• Dr Ram Sharma