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Biosensors based on type of biotransducers. A biotransducer is the recognition-transduction component of a biosensor system. It consists of two intimately coupled parts; a bio-recognition layer and a physicochemical transducer, which acting together converts a biochemical signal to an electronic or optical signal.
The biosensors are disposable, resulting in low costs and high commercial availability. [11] Biosensor selection is determined by the desired test results: kinetic analysis, quantitative analysis, or both. [12] Most commercially available biosensor types will be grouped into one of these three categories by the BLI manufacturer. [1]
Biosensors used for screening combinatorial DNA libraries. In a biosensor, the bioreceptor is designed to interact with the specific analyte of interest to produce an effect measurable by the transducer. High selectivity for the analyte among a matrix of other chemical or biological components is a key requirement of the bioreceptor.
Bio-FETs couple a transistor device with a bio-sensitive layer that can specifically detect bio-molecules such as nucleic acids and proteins. A Bio-FET system consists of a semiconducting field-effect transistor that acts as a transducer separated by an insulator layer (e.g. SiO 2) from the biological recognition element (e.g. receptors or probe molecules) which are selective to the target ...
Electrochemical aptamer-based (E-AB) biosensors is a device that takes advantage of the electrochemical and biological properties of aptamers to take real time, in vivo measurements. An electrochemical aptamer-based (E-AB) biosensor generates an electrochemical signal in response to specific target binding in vivo [ 3 ] The signal is measured ...
Clinical miRNA sample analysis commonly comes in blood, plasma, serum, seminal fluid, saliva, urine, and tissue-derived miRNAs. [54] In the context of cancer, biosensor detection of miRNAs is most conveniently performed in the form of liquid biopsies, as circulatory miRNAs are found in the highest abundance in liquid samples. [55]
In amperometric biosensors, an enzyme-catalyzed redox reaction causes a redox electron current that is measured by a working electrode. [11] Amperometric biosensors have been used in bio-MEMS for detection of glucose, galactose, lactose, urea, and cholesterol, as well as for applications in gas detection and DNA hybridization. [11]
Enzymatic glucose biosensors use an electrode instead of O 2 to take up the electrons needed to oxidize glucose and produce an electronic current in proportion to glucose concentration. [13] This is the technology behind the disposable glucose sensor strips used by diabetics to monitor serum glucose levels.