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Biosensors

Biosensors. Presented by: Dr. Manouchehr Bahrami Prepared by MEMS group University of Tabriz Department of Electrical and computer Eng. Outline. Introduction to Biosensors 2) Bioreceptors 3) Immobilization of Bioreceptors 4) Transduction methods and example devices.

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Biosensors

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  1. Biosensors Presented by: Dr. ManouchehrBahrami Prepared by MEMS group University of Tabriz Department of Electrical and computer Eng.

  2. Outline • Introduction to Biosensors 2) Bioreceptors 3) Immobilization of Bioreceptors 4) Transduction methods and example devices

  3. Introduction to Biosensors A biosensor is an analytical device which is used to determine the presence and concentration of a specific substance in a biological analyte Desired molecule Signal Processing Bioreceptor Transducer Display Biosample Biosensor Recognition Transduction Signal Processing

  4. Introduction to Biosensors Bioreceptor Transducer Absorption Fluorescence Antibody Optical Interference potentiometric Enzyme Electrochemical amperometric conductimetric Nucleic Acid (DNA) Mass based Cell Temperature based Dielectric properties Electric & Magnetic Permeability properties MIP Voltage or Current

  5. Bioreceptors • Antibody Antibodies are biological molecules that exhibit very specific binding capabilities for specific structure (antigens). • Antigen membrane It can be recognized by antibody.

  6. Bioreceptors Bioreceptor Display

  7. Bioreceptors • Enzyme Enzyme is a large protein molecule that acts as a catalyst in chemical reactions. Enzymes are often chosen as bioreceptors based on their specific binding capabilities as well as their catalytic activity

  8. Bioreceptors Bioreceptor Display

  9. Bioreceptors • DNA structure Four chemical bases: • adenine(A), guanine (G), • cytosine (C), and thymine (T) Another biorecognition mechanism involves hybridization of deoxyribonucleic acid (DNA) or ribonucleic acid (RNA), which are the building blocks of genetics.

  10. Bioreceptors Principles of DNA biosensors Nucleic acid hybridization (Target Sequence) ssDNA (Probe) (Hybridization) (Stable dsDNA)

  11. Bioreceptors Bioreceptor Display

  12. Bioreceptors • Living Cell Nourishment Product

  13. Bioreceptors Bioreceptor Display

  14. Bioreceptors • MIP (Molecular Imprinted Polymer)

  15. Bioreceptors MIP as a bioreceptor

  16. Bioreceptors Bioreceptor Display

  17. Immobilizatiom Physical Entrapment The immobilization is done either by physical entrapment or chemical attachment. Bioreceptor (Antibody, Enzyme, Cell, …) + polymer solution → polymerization Adsorption adsorptive interactions such as ionic, polar or hydrogen bonding and hydrophobic interaction.

  18. Immobilizatiom Covalent bounding formation of a stable covalent bond between functional groups of the bioreceptor components and the transducer Cross-linking bridging between functional groups on the outer membrane of the receptor by multifunctional reagents to transducer. The cells can be bounded directly onto the electrode surface or on a removable support membrane, which can be placed on the transducer surface

  19. conductimetric

  20. Transducers- Optical methods Concept: Capture analyte and detect binding by optical tag or binding-sensitive optical phenomenon Absorption I1/I0 = e−αlc lis the pass length C is the concentration of absorbing material αis the absorption coefficient

  21. Transducers- Optical methods- Absorption A device to determine a patient’s blood oxygen content: “the oximeter” The absorption spectra (α) of haemoglobin (Hb) and oxyhaemoglobin (HbO2) differ, which makes it possible to measure the ratio of both concentrations in blood by measuring the absorption of light of two different wavelengths, e.g. 660 nm and 805 nm.

  22. Transducers-Optical methods- Florescence Fluorescence is a molecular absorption of light at one wavelength and its instantaneous emission of at longer wavelengths. Some molecules fluoresce naturally and others such as DNA can be modified for fluorescence detection by attachment of special fluorescent dyes An optical system for Florescence measurement

  23. Transducers-Optical methods- Florescence Grating Antigens modified by florophor dye Evanescent-field. Planer waveguide Excitation light Florescence detector A device for florescence measurement

  24. Transducers-Optical methods- Florescence Taq-Man probe in its preliminary condition for real time PCR devive Releasing fluorophore dye during extension Hybridisation of primer and Taq-Man probe at annealing temperature

  25. Transducers-Optical methods- Florescence Photodiode pattern to reduce direct illumination Photodiode implanted at the bottom of the chamber and CdS film covers the photodiode Optical fibre used to introduce excitation energy Pyrex Si Pyrex Si Temperature sensor and heaters Real time Chamber PCR device with integrated fluorescence detection

  26. Transducers-Optical methods-refractive index Mach-Zehnder interferometer

  27. Transducers-Optical methods-refractive index The reflected wavelength (λB), called the Bragg wavelength, is defined by

  28. Transducers-Optical methods-refractive index Optical waveguide based biosensor

  29. Transducers-Electrochemical methods The underlying principle for this class of biosensors is that many chemical reactions produce or consume ions or electrons which in turn cause some change in the electrical properties of the solution which can be sensed out and used as measuring parameter

  30. Transducers-Electrochemical methods-amperometric amperometric glucose biosensors

  31. Transducers-Electrochemical methods-amperometric amperometric glucose biosensors

  32. Transducers-Electrochemical methods-potentiometric Schematic diagram of an integrated enzyme-based flow-through glucose sensor.

  33. Transducers-Electrochemical methods-potentiometric

  34. Transducers-Electric methods Concept: Capture analyte and detect changes in electrical parameters of sample Immunosensing at micro-sized Au electrodes based on the change of conductivity between the Au strips upon binding of Au nanoparticles

  35. Transducers-Electric methods Capacitive sensor by MIP dielectric Variation of

  36. Transducers-Electric methods F= 20KHz, AC amplitude of 40 mV peak to peak

  37. Transducers-Mass based methods The principle is to change in the frequency of vibrating element. when the mass increases due to binding of chemicals, the oscillation frequency of the device changes and the resulting change can be measured electrically and be used to determine the additional mass.

  38. Transducers-Mass based methods Detection by cantilevers

  39. Transducers-Mass based methods Detection by cantilevers Change in the resonance frequency: AcV1 antibody (green) and baculovirus particles (red).

  40. Transducers-Mass based methods Detection by cantilevers (a) A mechanical cantilever resonator containing an embedded microfluidic channel. (b) Decrease in resonant frequency as the density inside the embedded channel increases. (c) Frequency modulation by single particle movment

  41. Transducers-Mass based methods Detection by cantilevers Microcantilever technology: a) with immobilised protein for a specific bacterium b) bending after adsorption of bacteria to the protein

  42. Transducers-Mass based methods

  43. Transducers-Temperature methods This type of biosensor is exploiting one of the fundamental properties of biological reactions, namely absorption or production of heat, which in turn changes the temperature of the medium in which the reaction takes place. They are constructed by combining immobilized enzyme molecules with temperature sensors. When the analyte comes in contact with the enzyme, the heat reaction of the enzyme is measured and is calibrated against the analyte concentration. The total heat produced or absorbed is proportional to the molar enthalpy and the total number of molecules in the reaction

  44. Transducers-Temperature methods A three-dimensional schematic representation of the proposed microcalorimeter with integrated microfluidic channels.

  45. Thank you for your attention ?

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