 Press Release
Advanced Materials 2006, 18, 1511–1516
doi: 10.1002/adma.200600120 Nr. 12/2006 Simultaneous analysisSimultaneous carbon dioxide and oxygen sensingContact: Otto Wolfbeis, University of Regensburg (Germany)
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Composite Material for Simultaneous and Contactless Luminescent Sensing and Imaging of Oxygen and Carbon Dioxide
Breathing. Birds, do it, bees do it, even educated trees do it. But,
only plants can make sugars from the carbon dioxide byproduct and at the
same time expel oxygen during photosynthesis. This amazing skill has
intrigued scientists for decades but separating out the carbon dioxide
inputs and outputs while keeping tabs on oxygen levels has always proved
difficult.
Now, a new type of chemical sensor, described in the journal Advanced
Materials, could change all that. The sensor developed by Otto
Wolfbeis and colleagues at the Institute of Analytical Chemistry, Chemo-
and Biosensors at the University of Regensburg, Germany, will allow
clearer insights into plant respiration and photosynthesis. It could
also have application in the food and drink industry as well as in the
biotech industry where fermentation and related plant processes are
important.
Woflbeis explains that in order to unravel the intricacies of
photosynthesis and respiration, two of the most important biochemical
processes, scientists have to be able to measure carbon dioxide and
oxygen at the same time. He and his team have now found a way to
side-step the interference from which all previous sensors suffer. The
team first create nanoparticles carrying a fluorescent group that react
to light and glow only when they are in contact with carbon dioxide
molecules.
These nanoparticles are then embedded in a layer of polymer resin. A
second compound that does the same in the presence of oxygen molecules
is embedded in a second layer of polymer and the two films sandwich
between them a layer of an organometallic compound containing the heavy
metal iridium. This layer produces a reference signal for the detection
of fluorescence triggered by the two gases. Importantly, however, it is
impermeable to oxygen molecules and so its light is not quenched by
interference from oxygen.
A blue light-emitting diode (LED) then provides the stimulation for the
two sensitive layers to produce light, but only in the presence of their
respective gases. A tiny photodetector can then measure the wavelength
of light emitted, which is different from each sensor molecule. The
strength of the emitted light at each wavelength correlates with the
concentration of each of the two gases.
The team tested their sensor over a wide range of different carbon
dioxide and oxygen concentrations produced by a growing microbial
culture and found it to operate with a remarkable ±5% accuracy at
concentration levels expected for real experiments. At much higher but
unrealistic concentrations, accuracy deviated only by as much ±10%.
Because the device is designed to be reusable rather than a one-shot dip
test, the team tested its response after several hundred runs and found
it to still be working at these levels of accuracy after 800 runs.
They anticipate that their composite material will become a powerful
tool in biological, biotechnological, and medical research. The
simultaneous sensor could also have applications in environmental
monitoring of sea water and sewage and in medical diagnostics, where
blood gas levels are important to understanding the progression of
certain diseases.
The research will be commercialized by Presens GmbH (see http://www.presens.de).
“It is likely to become a powerful tool in combinatorial microbiology,
in cell-based screening for drugs, and in biomonitoring in general,"
Wolfbeis explains. "In combination with fiber optic microsensors, in
vivo sensing of oxygen and carbon dioxide should be possible.”
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