MICROBIAL APPLICATIONS
ENVIRONMENTAL MICROBIOLOGY
BIOL/CEE/CSES/ENSC 4164
Biosensors and Biochips
The high degree of specificity exhibited by the actions of enzymes,
antibodies, and membrane receptors offers the potential of developing
sensors or detectors that possess unparalleled chemical recognition
properties. Biotechnologists are beginning to exploit this vast resource of
sensors and, where this exquisite biological sensitivity can be coupled to
the unique ability of microelectronic circuits to amplify and process minute
electronic signals, biosensors capable of detecting extremely low levels of
proteins, hormones, pollutants, gases, and other molecules can be developed.
Diagnosis, Health, and Safety
Biosensors will assist doctors in making rapid diagnoses. They are finding
applications in industry, where they permit rapid detection and measurement
of acids, alcohols, and phenols. Diagnostic kits for the detection of small
amounts of drugs in humans are assisting the police and doctors in assessing
drug abuse. Advanced systems are being developed in which biosensors are
coupled to alarm systems warning workers of dangers before they reach
critical levels. The benefits in health and safety at the workplace will be
considerable.
Bugs and Computers
In a typical biosensor, the substance to be detected or measured (the
substrate) passes through a thin protective membrane or gel before
encountering the biological sensing agent. These outer coatings allow access
to the sensing agent, but must provide a degree of stability and minimize
fouling of the device. The sensing agent is normally an enzyme or an
antibody, but improved cell immobilization methods mean that in some cases
whole cells can be used. Substrate and sensor interact, the result of which
is detected as a change in electrical capacitance or conductance. It may be
a temperature change, a mass or optical change, the production of a gas, or
a new chemical that is detected. An appropriate transducer is then used to
detect and measure the product, resulting finally in an electrical signal,
which can be amplified to the required level. In this way an immediate
readout can be provided - the biosensor has "sensed" successfully.
An example is the use of the immobilized enzyme glucose oxidase, which
releases electrons on interaction with glucose. A sensor of this type could
detect continuously the level of glucose in the blood - a function of the
human pancreas which is deficient in diabetic patients. If coupled with a
minipump triggered to respond as required, the functions of a normal
pancreas can be restored, giving a maintained, appropriate level of blood
insulin - a considerable improvement on the inevitable peaks and troughs
experienced by diabetics receiving regular insulin injections.
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URL http://soils1.cses.vt.edu/ch//biol_4684/biosensors.html
Last Updated 6/29/98