There are many potential applications of biosensors of various types. The main requirements for a biosensor approach to be valuable in terms of research and commercial applications are the identification of a target molecule, availability of a suitable biological recognition element, and the potential for disposable portable detection systems to be preferred to sensitive laboratory-based techniques in some situations. Some examples are: •
glucose monitoring in diabetes patients, other medical health related targets, • environmental applications, e.g. the detection of
pesticides, detection and determining of
organophosphate, and river water contaminants, such as heavy metal ions, • remote sensing of airborne
bacteria, e.g. in counter-bioterrorist activities, • remote sensing of water quality in coastal waters by describing online different aspects of clam ethology (biological rhythms, growth rates, spawning or death records) in groups of abandoned bivalves around the world, and • detection of toxic metabolites such as
mycotoxins. A common example of a commercial biosensor is the
blood glucose biosensor, which uses the enzyme
glucose oxidase to break blood glucose down. In doing so it first oxidizes glucose and uses two electrons to reduce the FAD (a component of the enzyme) to FADH2. This in turn is oxidized by the electrode in a number of steps. The resulting current is a measure of the concentration of glucose. In this case, the electrode is the transducer and the enzyme is the biologically active component. A
canary in a cage, as used by miners to warn of gas, could be considered a biosensor. Many of today's biosensor applications are similar, in that they use organisms which respond to
toxic substances at a much lower concentrations than humans can detect to warn of their presence. Such devices can be used in
environmental monitoring, trace gas detection and in water treatment facilities.
Glucose monitoring Commercially available glucose monitors rely on
amperometric sensing of glucose by means of
glucose oxidase, which oxidises glucose producing hydrogen peroxide which is detected by the electrode. To overcome the limitation of amperometric sensors, a flurry of research is present into novel sensing methods, such as
fluorescent glucose biosensors.
Interferometric reflectance imaging sensor The interferometric reflectance imaging sensor (IRIS) is based on the principles of
optical interference and consists of a silicon-silicon oxide substrate, standard optics, and low-powered coherent LEDs. When light is illuminated through a low magnification objective onto the layered silicon-silicon oxide substrate, an interferometric signature is produced. As biomass, which has a similar
index of refraction as silicon oxide, accumulates on the substrate surface, a change in the interferometric signature occurs and the change can be correlated to a quantifiable mass.
Daaboul et al. used IRIS to yield a label-free sensitivity of approximately 19 ng/mL.
Ahn et al. improved the sensitivity of IRIS through a mass tagging technique. Since initial publication, IRIS has been adapted to perform various functions. First, IRIS integrated a fluorescence imaging capability into the interferometric imaging instrument as a potential way to address fluorescence protein microarray variability. Briefly, the variation in fluorescence microarrays mainly derives from inconsistent protein immobilization on surfaces and may cause misdiagnoses in allergy microarrays. To correct for any variation in protein immobilization, data acquired in the fluorescence modality is then normalized by the data acquired in the label-free modality. This modality enables size discrimination in complex human biological samples.
Monroe et al. used IRIS to quantify protein levels spiked into human whole blood and serum and determined allergen sensitization in characterized human blood samples using zero sample processing. Other practical uses of this device include virus and pathogen detection.
Food analysis There are several applications of biosensors in food analysis. In the food industry, optics coated with antibodies are commonly used to detect pathogens and food toxins. Commonly, the light system in these biosensors is fluorescence, since this type of optical measurement can greatly amplify the signal. A range of immuno- and ligand-binding assays for the detection and measurement of small molecules such as
water-soluble vitamins and chemical contaminants (
drug residues) such as
sulfonamides and
Beta-agonists have been developed for use on
SPR based sensor systems, often adapted from existing
ELISA or other immunological assay. These are in widespread use across the food industry.
Detection/monitoring of pollutants Biosensors could be used to monitor
air,
water, and soil pollutants such as pesticides, potentially carcinogenic, mutagenic, and/or toxic substances and endocrine disrupting chemicals.
Ozone measurement Because
ozone filters out harmful ultraviolet radiation, the discovery of holes in the ozone layer of the earth's atmosphere has raised concern about how much
ultraviolet light reaches the earth's surface. Of particular concern are the questions of how deeply into sea water ultraviolet radiation penetrates and how it affects
marine organisms, especially
plankton (floating microorganisms) and
viruses that attack plankton. Plankton form the base of the marine food chains and are believed to affect our planet's temperature and weather by uptake of CO2 for photosynthesis. Deneb Karentz, a researcher at the Laboratory of Radio-biology and Environmental Health (
University of California, San Francisco) has devised a simple method for measuring ultraviolet penetration and intensity. Working in the Antarctic Ocean, she submerged to various depths thin plastic bags containing special strains of
E. coli that are almost totally unable to repair ultraviolet radiation damage to their DNA. Bacterial death rates in these bags were compared with rates in unexposed control bags of the same organism. The bacterial "biosensors" revealed constant significant ultraviolet damage at depths of 10 m and frequently at 20 and 30 m. Karentz plans additional studies of how ultraviolet may affect seasonal plankton
blooms (growth spurts) in the oceans.
Metastatic cancer cell detection Metastasis is the spread of cancer from one part of the body to another via either the circulatory system or lymphatic system. Unlike radiology imaging tests (mammograms), which send forms of energy (x-rays, magnetic fields, etc.) through the body to only take interior pictures, biosensors have the potential to directly test the malignant power of the tumor. The combination of a biological and detector element allows for a small sample requirement, a compact design, rapid signals, rapid detection, high selectivity and high sensitivity for the analyte being studied. Compared to the usual radiology imaging tests, biosensors have the advantage of not only finding out how far cancer has spread and checking if treatment is effective but also are cheaper, more efficient (in time, cost and productivity) ways to assess metastaticity in early stages of cancer. Biological engineering researchers have created oncological biosensors for breast cancer. Breast cancer is the leading common cancer among women worldwide. An example would be a transferrin- quartz crystal microbalance (QCM). As a biosensor,
quartz crystal microbalances produce oscillations in the frequency of the crystal's standing wave from an alternating potential to detect nano-gram mass changes. These biosensors are specifically designed to interact and have high selectivity for receptors on cell (cancerous and normal) surfaces. Ideally, this provides a quantitative detection of cells with this receptor per surface area instead of a qualitative picture detection given by mammograms. Seda Atay, a biotechnology researcher at Hacettepe University, experimentally observed this specificity and selectivity between a QCM and
MDA-MB 231 breast cells,
MCF 7 cells, and starved MDA-MB 231 cells in vitro.
Pathogen detection Biosensors could be used for the detection of pathogenic organisms. Embedded biosensors for pathogenic signatures – such as of
SARS-CoV-2 – that are
wearable have been developed – such as
face masks with built-in tests. See also:
COVID-19 public transport R&D New types of biosensor-chips could enable novel methods "such as drone-deployed pathogen sensors actively surveying air or wastewater". Protein-binding aptamers could be used for testing for infectious disease pathogens. Systems of
electronic skins (or robot skins) with built-in biosensors (or chemical sensors) and human-machine interfaces may enable wearable as well as
remote sensed device- or
robotic-sensing of pathogens (as well as of several hazardous materials and
tactile perceptions). == Types ==