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WO2022227076A1 - Bioaerosol detection device - Google Patents

Bioaerosol detection device Download PDF

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Publication number
WO2022227076A1
WO2022227076A1 PCT/CN2021/091724 CN2021091724W WO2022227076A1 WO 2022227076 A1 WO2022227076 A1 WO 2022227076A1 CN 2021091724 W CN2021091724 W CN 2021091724W WO 2022227076 A1 WO2022227076 A1 WO 2022227076A1
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WO
WIPO (PCT)
Prior art keywords
bioaerosol
detection
air
detection device
oil
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PCT/CN2021/091724
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French (fr)
Chinese (zh)
Inventor
黄荣堂
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奇异平台股份有限公司
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Priority to PCT/CN2021/091724 priority Critical patent/WO2022227076A1/en
Publication of WO2022227076A1 publication Critical patent/WO2022227076A1/en

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    • GPHYSICS
    • G01MEASURING; TESTING
    • G01NINVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
    • G01N1/00Sampling; Preparing specimens for investigation
    • G01N1/02Devices for withdrawing samples
    • G01N1/22Devices for withdrawing samples in the gaseous state
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01NINVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
    • G01N27/00Investigating or analysing materials by the use of electric, electrochemical, or magnetic means
    • G01N27/02Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating impedance
    • G01N27/04Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating impedance by investigating resistance

Definitions

  • the invention relates to the technical field of biological aerosol detection, in particular to a biological aerosol detection device.
  • pathogens are known to spread through the air from person to person, including viruses such as influenza, coronaviruses such as SARS, MERS, COVID-19, chicken pox, and rubeola ( measles), Norovirus, or Calicivirus, and bacteria such as tuberculosis, Bordetella whooping cough, and methicillin-resistant Staphylococcus aureus (such as pneumonia).
  • viruses such as influenza, coronaviruses such as SARS, MERS, COVID-19, chicken pox, and rubeola ( measles), Norovirus, or Calicivirus, and bacteria such as tuberculosis, Bordetella whooping cough, and methicillin-resistant Staphylococcus aureus (such as pneumonia).
  • viruses such as influenza, coronaviruses such as SARS, MERS, COVID-19, chicken pox, and rubeola ( measles), Norovirus, or Calicivirus
  • bacteria such as tuberculosis
  • Impingers are liquid collection-based samplers that rely on a 5mL or 20mL working volume
  • filters and impingers are dry-collection-based samplers that rely on elution steps to extract the collection from their respective solid supports virus. This elution can result in a large final extracted sample volume, typically several milliliters. If only a small number of viral particles are present in the sampled air volume, these large volumes produce huge dilutions, making these methods unsuitable for low limit of detection (LoD) measurements.
  • the integration and automation of handling and processing of liquid volumes from impactors, filters or impactors to biosensors requires significant system complexity and is not suitable for point-of-care (PoC) applications.
  • BioSamplers (SKC Inc.) with a 220V SKC BioLite Sampling Pump (SKC Inc.) for bioaerosol sampling.
  • the sampler was connected to an in-line steam trap (SKC Inc.) to protect the pump from moisture, and the pump was allowed to run for 5 minutes to warm up before sampling.
  • the SKC BioSampler was filled with 15 ml sterile phosphate buffered saline (PBS) containing 0.5% (w/v) bovine serum albumin fraction V (BSA) powder and placed 1-1.5 m above the ground.
  • PBS sterile phosphate buffered saline
  • BSA bovine serum albumin fraction V
  • the pump was turned off, the BioSampler was disconnected, and the sample medium was aseptically transferred from the SKC Bio-Sampler collection container to a sterile 15 ml conical tube. Sent for quantitative polymerase chain reaction (qPCR). All samplers were autoclaved at the end of each sampling day.
  • the in situ sensing device seems to be able to combine the biosensor with the back end of the bioaerosol collector to achieve the detection goal of POC.
  • current multifunctional tools such as Lab on a chip (LoC) biosensors are only suitable for liquid samples.
  • LoC Lab on a chip
  • compatible air sampling and air-liquid interface technologies must be developed.
  • after sampling it is possible to connect to a chip that can perform on-site detection immediately, which requires both precision and real-time.
  • an interdisciplinary approach is necessary, and the present invention addresses this issue.
  • the present invention aims to solve one of the technical problems in the above technologies at least to a certain extent.
  • one object of the present invention is to propose a bioaerosol detection device that solves the incompatibility problem of air sampling and liquid-based sensing technologies.
  • the second object of the present invention is to propose a method for bioaerosol detection, which solves the incompatibility problem of air sampling and liquid-based sensing technology.
  • a bioaerosol detection device including:
  • the collection module includes a suction fan, an arc-shaped tapered air passage, a first pump, an oil-water container, and a second pump;
  • the oil-water container is provided with an oil layer and a biological buffer;
  • the air inlet of the suction fan is provided with a filter unit , to preliminarily filter the inhaled air, and generate impact force through the arc-shaped tapered airway to collect the bio-aerosol in the air above the oil layer of the oil-water container, so that the bio-aerosol is adsorbed on the surface of the oil layer, and then periodically passes through the first
  • the pump hits the pressure air on the surface of the oil layer to turn the oil layer.
  • the bioaerosol to be tested is turned under the oil layer and enters the biological buffer;
  • the detection module includes a sensing chip unit, a signal processing unit, and a microcontroller unit, and each unit is electrically connected; at least one detection molecule is fixed on the sensing chip unit to detect a specific biological aerosol entering the biological buffer;
  • Power supply the power supply the power required by the collection module and the detection module
  • the bioaerosol to be tested entering the biological buffer solution is designed with a circulating flow channel and driven by the second pump, so that the biological buffer solution and the bioaerosol to be tested under the oil layer will circulate through the sensing chip unit.
  • the bioaerosol to be tested is effectively contacted with the detection molecules to achieve capture and detection.
  • the bioaerosol to be tested entering the biological buffer solution is designed with a circulating flow channel and driven by the second pump, so that the biological buffer solution under the oil layer and the waiting
  • the bioaerosols to be measured will circulate through the sensor chip unit, so that the bioaerosols to be measured can effectively contact aptamers or antibodies to achieve capture and detection, thereby solving the incompatibility between air sampling and liquid-based sensing technologies.
  • bioaerosol detection device proposed according to the above embodiments of the present invention may also have the following additional technical features:
  • the bioaerosol includes at least one of viruses, germs, fungi, and pollen.
  • the detection module includes a wireless communication module or a display unit.
  • the redox ions contained in the biological buffer are selected from red blood salt, yellow blood salt, ruthenium hexaammine, and enzymes.
  • the probe molecules are selected from aptamers, antibodies or carbohydrate molecules.
  • nanomaterials used for aptamers or antibodies for capturing the target are added on the sensing chip, and the nanomaterials are selected from nanomagnetic beads, nanogold, carbon tubes, graphene, ZnO, and these nanomaterials are further combined with thionine or Prussian blue.
  • the detection method of the sensing chip unit is an optical method selected from surface plasmon method, colorimetric method, chemiluminescence method, fluorescence method, surface enhanced Raman scattering method and interference method.
  • the detection method of the sensing chip unit is an electrical method.
  • the concentration of the target can be detected.
  • device method field effect transistor method, nanopore.
  • the signal processing unit of the electrical method is mainly selected from amperometric method, square wave voltammetry, differential pulse wave voltammetry, chronoamperometry, intermittent pulse amperometric method, fast scanning cyclic voltammetry, electrochemical impedance spectroscopy, Field-effect enzyme assays or combinations thereof.
  • a second aspect of the embodiments of the present invention provides a method for detecting biological aerosols, using the above-mentioned biological aerosol detecting device, including the following steps:
  • Step 1 filter, remove the non-target biological aerosol from the air to be tested;
  • Step 2 air extraction, and the ambient air is sucked into the device by an air intake fan;
  • Step 3 capturing and collecting, impacting the bioaerosol into the oil film/biological buffer in the device, so that the bioaerosol adheres to the oil film, or passes through the oil film and directly enters the biological buffer;
  • Step 4 The biological aerosol is converted into a hydrosol, and the tapered airway of the detection device is used to generate an impact force, or the first pump blows the aerosol captured above the oil film and flips the oil film into the biological buffer to become a hydrosol;
  • Step 5 Concentrating mass transfer, using the design of the circulating flow channel, all the hydrosols in the biological buffer flow to the sensing chip and the detection molecules on the chip are captured and combined;
  • the sixth step, detection utilizes the detection molecules on the sensing chip to capture and bind, and the resulting signal changes to detect the concentration of the target bioaerosol.
  • FIG. 1 is a functional block diagram of a bioaerosol detection module according to an embodiment of the present invention
  • FIG. 2A is a schematic diagram of the internal structure of a bioaerosol detection device according to an embodiment of the present invention.
  • FIG. 2B is a schematic three-dimensional structure diagram of a bioaerosol detection device according to an embodiment of the present invention.
  • FIG. 3 is a schematic diagram of the air flow directions of the air intake and the air outlet of the bioaerosol detection device according to an embodiment of the present invention
  • FIG. 4A is a configuration diagram of an intake fan, a first pump, and a second pump of a bioaerosol detection device according to an embodiment of the present invention
  • FIG. 4B is a 1/4 sectional view of FIG. 4A of the bioaerosol detection device according to an embodiment of the present invention
  • 4C is a schematic diagram of the flow direction of the first pump actuation of the bioaerosol detection device according to an embodiment of the present invention.
  • 5A is a schematic diagram of the flow direction of the second pump actuation water flow of the bioaerosol detection device according to an embodiment of the present invention
  • 5B is a schematic diagram of the flow direction of the second pump actuation water flow of the bioaerosol detection device according to an embodiment of the present invention.
  • 5C is a schematic diagram of the distribution of the bioaerosol to be measured when the second pump of the bioaerosol detection device according to the embodiment of the present invention is not actuated;
  • 5D is a schematic diagram of the distribution of the bioaerosol to be detected in the second pumping action of the bioaerosol detection device according to the embodiment of the present invention.
  • FIG. 6 is a schematic structural diagram of a sensing chip of a bioaerosol detection device according to an embodiment of the present invention.
  • FIG. 7 is a schematic diagram of a field-effect enzyme sensing platform of an embodiment of a bioaerosol detection device according to an embodiment of the present invention.
  • FIG. 8 is a schematic structural diagram of a field-effect enzyme sensing chip of an embodiment of a bioaerosol detection device according to an embodiment of the present invention.
  • Wireless communication module 18 Power supply module 19
  • Circulating waterway 55 The direction of water flow 57
  • the bioaerosol detection module 1 of the present invention mainly needs to achieve three goals, as shown in FIG. 1 , FIG. 2A , FIG. 2B and FIG. 3 , first, in a general environment, the ambient air 5 that may contain bioaerosols is extracted by The air fan 11 is drawn into the filter unit 10 to purify the bio-aerosol to be tested, and the bio-aerosol to be tested will not be affected by the filtering method on its surface biochemical properties.
  • the parameters of the flow rate and pressure are adjusted to generate an impact force to push the bioaerosol in the air into the oil film 33 of the oil film/biological buffer container 13, so that the bioaerosol can be adsorbed On the surface of the oil film 33, and then the pressure wind is periodically hit on the surface of the oil film 33 through the first pump 24, so that the oil film 33 is turned over.
  • the biological aerosol to be tested entering the biological buffer 35 is driven by the second pump 27 through a special flow channel design, so that the biological buffer 35 under the oil film 33 and the biological aerosol to be tested will be Circulating flow through the sensing chip 14 makes the bioaerosol to be tested effectively contact with the specific aptamer or antibody, so as to achieve nearly 100% capture and detection.
  • the biological buffer 35 may be Phosphate-buffered saline (Phosphate-buffered saline, PBS).
  • the first pump 24 is a small pump
  • the second pump is a peristaltic pump
  • biological buffers such as PBS
  • the biological buffer also known as Good's Buffers
  • Chemicals help to regulate and maintain the pH of the reaction environment within the physiological pH range.
  • the source can be taken from Hopax, one of the largest manufacturers of Good's Buffers in the world.
  • Good's Buffers have the following characteristics: pKa value between 6 and 8, good water solubility, non-toxic, not easy to interfere with biochemical reactions, not easy to penetrate cell membranes, good stability to enzymes and hydrolysis, not easy to change with environmental temperature changes , and limited interaction with mineral cations.
  • FIG. 2A is a schematic diagram of the internal structure of a bio-aerosol detection device according to an embodiment of the present invention
  • FIG. 2B is a schematic diagram of a three-dimensional structure of a bio-aerosol detection device according to an embodiment of the present invention.
  • the bio-aerosol detection device includes a base 28 and an upper cover. 29.
  • the suction fan 11, the first pump 24, the sensing chip 14 and the second pump 27, the suction fan 11, the first pump 24, the sensing chip 14, and the second pump 27 are arranged on the base,
  • the upper cover 29 is covered on the base 28 .
  • the preferred embodiment of the filter unit 10 is two layers, the first layer is to filter the larger dust particles in the air, and the filter of the large particles is generally visible to the naked eye.
  • the first layer is to filter the larger dust particles in the air
  • the filter of the large particles is generally visible to the naked eye.
  • For particles use commercially available filter cotton for the first layer of filtration, and the second layer of filtration to filter fine particles in the air.
  • the test object is a germ, and its size is about 1-2um; or an influenza virus, its size is about 80-120nm, in order to achieve the accuracy of detection, the method is to use a suitable filter device, because the direction of the present invention is to capture the germs in the air Or influenza virus, however, the bacteria or influenza virus may not be accompanied by water droplets in the air, so a dry-to-wet mechanism must be provided on the surface of the chip, so that the bacteria or virus can pass through this mechanism to accelerate the bacteria or influenza virus and infection.
  • a dry-to-wet mechanism must be provided on the surface of the chip, so that the bacteria or virus can pass through this mechanism to accelerate the bacteria or influenza virus and infection.
  • the present invention uses an exhaust fan 11 and a filter unit 10, wherein two filter devices can be set in the filter unit 10, the sensor chip 14 and the signal reading module 16 perform biological
  • the microcontroller 17 performs adjustment and control
  • the wireless communication module 18 has a communication function
  • the power supply module 19 supplies power to the exhaust fan 11 , the sensing chip 14 and the signal reading module 16 .
  • the present invention mainly uses the exhaust fan 11 to generate forced convection of the ambient air, so that the ambient air can enter the detection device more efficiently, and the air will contact the designed air duct after entering.
  • the oil film 33 most of the microorganisms or viruses will be attached to the surface of the oil film 33. In order for the microorganisms or viruses on the oil film 33 to pass through the oil film 33 and contact with the PBS 35, a strong positive pressure is required above the oil film 33 to blow down the oil film 33.
  • the first small pump (small pump) 24 is used to inhale the strong positive pressure from above, so that the oil film 33 can be turned over.
  • the purpose of using the oil film 33 here is to Let the PBS stay in the open space for a long time, and it will not volatilize and reduce its volume, thereby affecting the detection accuracy of the target to be measured.
  • the preferred embodiment of the oil film 33 is various types of mineral oil, salad oil, or other substances that will not kill the target.
  • the oil of the bioaerosol also does not react with PBS or its additives, such as red blood salt/yellow blood salt, or other redox ions (redox), and can be maintained for several months without much volatilization.
  • This innovative method eliminates the need for automatic water supply devices to replenish PBS in the container, maintains the thickness of the oil film/PBS within a fixed volume, and ensures that the concentration of PBS or its additives remains nearly constant.
  • the thickness of the oil film 33 is designed in the range of 0.1mm to 3mm, preferably in the range of 0.5mm-1mm.
  • the thickness of the oil film 33 must be sufficient so that the blow-off oil film 33 can be turned over and quickly (eg, within 0.5 seconds to 5 seconds) to restore the complete coverage of the PBS by the oil film 33 .
  • pathogens such as viruses or germs that are harmful to humans or animals are hydrophilic, so they are collected on the oil film 33 and blown onto the oil film 33, causing the oil film 33 to turn over and let the pathogens contact PBS, and the pathogens will enter hydrophilically.
  • PBS the effect of effectively collecting airborne pathogens into PBS can be achieved.
  • the first pump small pump
  • the method is that the suction fan can be large During a period of time, it works at a slow speed to collect aerosols on the oil film 33, and another period of time works at a high speed to generate a strong positive pressure and at the same time, the oil film 33 is turned over.
  • the oil film 33 is used for collection, and the oil film 33 has an adsorption effect on the target, but at the same time, it may also adsorb the impurities passing through the first filter. Therefore, when these targets and impurities are turned over into the PBS under the oil film 33, and the target bioaerosol is turned over to the PBS, the second pump 27 is used to add a closed-loop circulating water circuit 55, as shown in Figure 4A, Figure 4B, As shown in FIG. 4C and FIG. 5A and FIG.
  • the target bioaerosol is continuously circulated in the water flow direction 57, and each time it flows through the sensing chip 14, there is a chance to be detected by aptamers, antibodies, or sugar molecules on the working electrode.
  • Molecules 53 capture as shown in Figure 5C and Figure 5D, the flow rate is adjusted properly, PBS can flow, but the target bioaerosol that has been bound to probe molecules such as specific aptamers or antibodies will not be detached. In this way, basically, the target bioaerosol in the PBS will eventually bind specifically to the aptamer on the working electrode. Therefore, the concentration of the target bioaerosol in the PBS can be quantitatively obtained by reading the signal of the circuit.
  • the target bioaerosol such as virus 51 is very small, and because of the movement mode of diffusion, it is a random action, and it is difficult to have a chance to move to the vicinity of the detection molecule 53 of the working electrode, and interact with the detection molecule.
  • the combination of 53, that is, concentrated mass transfer is a necessary means to improve the sensitivity of detection.
  • a small circulating flow rate is given to the solution, so that the movement of virus 51 becomes a directional movement, especially in the vertical direction.
  • Working electrode and let the flow rate be very small, or flow for a period of time, and stand still for a period of time, giving a chance for stable combination, and also perform signal measurement and processing at the same time.
  • the present invention therefore does not require the usual sampling methods of bioaerosols described above and must rely on laboratory analysis of captured particles.
  • the present invention can effectively achieve sensitive detection, identification and quantification directly to the sampling point.
  • optical including surface plasmon resonance (SPR), colorimetric (colorimetric) method, chemiluminescence method (chemiluminescence, CL), fluorescence (fluorescence), surface-enhanced Raman scattering (surface-enhanced Raman scattering, SERS) and interference (interferometry).
  • SPR surface plasmon resonance
  • colorimetric colorimetric
  • chemiluminescence method chemiluminescence, CL
  • fluorescence fluorescence
  • surface-enhanced Raman scattering surface-enhanced Raman scattering
  • interference interference
  • the embodiment of the sensing chip measurement 24 can also use an electrical method.
  • the concentration of the target can be detected.
  • it can be divided into electrical method, piezoelectric transducer method, or field effect transistor (FET) method.
  • FET field effect transistor
  • Nanopores can also be used, (see Niedzwiecki, D.J., Iyer, R., Borer, P.N., and Movileanu, L. (2013). Sampling a biomarker of the human immunodeficiency virus across a synthetic nanopore.
  • the signal processing unit described in the electrical method is mainly selected from electrochemical sensing circuits, amperometric methods, square wave voltammetry (SWV), differential pulse voltammetry (Differential Pulse Voltammetry) , DPV), chronoamperometry (chronoamperometry), intermittent pulse amperometry (intermittent pulse amperometry, IPA), fast-scan cyclic voltammogram (fast-scan cyclic voltammogram, FSCV), electrochemical impedance spectroscopy (Electrochemical Impedance Spectrum, EIS) ) or a combination thereof.
  • electrochemical sensing circuits amperometric methods, square wave voltammetry (SWV), differential pulse voltammetry (Differential Pulse Voltammetry) , DPV), chronoamperometry (chronoamperometry), intermittent pulse amperometry (intermittent pulse amperometry, IPA), fast-scan cyclic voltammogram (fast-scan
  • some embodiments may modify the sensing chip 14 by adding nanomaterials to support aptamers or antibodies for capturing the target, and some nanomaterials are also involved in signal conversion. Increase the sensitivity of the sensor.
  • These nanomaterials include nanomagnetic beads, nanogold, carbon tubes, graphene, ZnO, etc. These nanomaterials were further combined with thionine (THI) or Prussian Blue (PB) to enhance the redox reaction during electrochemical detection.
  • the present invention is particularly illustrated by using an example of Electrochemical Impedance Spectrum (EIS), the sensing chip 14 can be made of a gold working electrode, the solution PBS is added with red blood salt/yellow blood salt 5mM or other redox ions, such as six Ammonium ruthenium(II)/(III) (Hexaammineruthenium(II)/(III)), can prolong the use and storage time.
  • EIS Electrochemical Impedance Spectrum
  • the sensing chip 14 can be made of a gold working electrode
  • the solution PBS is added with red blood salt/yellow blood salt 5mM or other redox ions, such as six Ammonium ruthenium(II)/(III) (Hexaammineruthenium(II)/(III))
  • LOD limit of detection
  • electrochemical impedance spectroscopy can also be used, but a Faraday measurement method is used, that is, the gold electrodes are formed into a comb-like interdigitated structure, and the spacing between the positive and negative electrodes is 10-50 microns. Then the concentration of bacteria and viruses is proportional to the impedance change.
  • the aptamer/enzyme combination 71 is first coated on the area other than the electrodes of the replaceable sensor chip 14 .
  • insert the sensing chip 14 into the PBS of the device of the present invention so that the aptamer/enzyme conjugate 71 is dissolved in PBS, so that the first aptamer 711 in the conjugate 71 can interact with the aptamer captured in the PBS.
  • the germs or viruses 72 are specifically bound, and at the same time, these germs or viruses 72 with the binding bodies 71 will also be close to the sensing chip 14 due to the circulating water flow, and thus bind to the second aptamer 73 immobilized on the working electrode WE on the chip.
  • aptamer/enzyme conjugates 71 that will combine with the bacteria or viruses captured by the second aptamer 73 on the chip working electrode WE to form a sandwich.
  • the enzyme 712 in the aptamer/enzyme combination 71 is selected from oxidoreductases such as horseradish peroxidase (Horseradish peroxidase, HRP), and the aptamer/enzyme (aptamer-biotin-streptavidin-HRP) is formed through a coupling procedure.
  • the detection platform is based on Field Effect Enzymatic Detection (FEED) technology.
  • the method uses an immunoassay platform to directly detect bacteria or viruses in samples without culture enrichment.
  • FIG. 7 is a schematic diagram of a field-effect enzyme detection platform according to an embodiment of the present invention.
  • the gate voltage 74 induces an electric field at the solution-enzyme-electrode interface to reduce the tunneling barrier for electrons. Therefore, the tunneling current between the electrodes and the HRP, the signal current, is amplified by the gate voltage 74 .
  • the platform provides ultra-sensitive quantitative detection of viruses and bacteria due to signal amplification, which can directly detect viruses or bacteria in bioaerosols in extremely low-concentration samples without sample processing.
  • the second aptamer 73 is first fixed to the working electrode WE.
  • Gating electrode GE 75 for example, use thick copper foil tape to spray insulating paint, or enameled copper wire, etc., to make a U shape, as shown in Figure 8, one end is welded with gold fingers, and the other end is free. This method is suitable for detecting bacteria and viruses.
  • the assay is based on the amplification of the horseradish peroxidase (HRP) reduction peak current, and the peak height is measured by drawing a baseline and judged by the cyclic voltammogram (CV).
  • HRP horseradish peroxidase
  • the related proteins may appear in the host infected by the virus or bacteria, and may appear in the droplets of the host, so an all-in-one sensor is used. , which can increase the sensitivity and accuracy of the sensing.
  • the proteins of its viral structure include Spike glycoprotein, Envelope protein, TransMembrane glycoprotein, nuclear Capsid protein (Nucleocapsid protein), etc.
  • fixed detection molecules can be implanted on the working electrode of the all-in-one sensor chip, and selected from Spike glycoprotein (Spike glycoprotein), Envelope protein (Envelope protein), Transmembrane glycoprotein (TransMembrane glycoprotein), nucleocapsid protein (Nucleocapsid protein), antibodies or aptamers, or nucleotide molecules against ssRNA.
  • the antibody against Spike glycoprotein can be one of IgA, IgM, and IgG, or both of IgG and IgM, or both of IgA and IgG, or three of IgA, IgM, and IgG.
  • the device of the present invention can estimate the concentration Ct of the air target bioaerosol
  • Remove modules such as PBS reservoir, PBS/oil film, etc.
  • Disinfection Wipe or spray the remaining modules and equipment with alcohol, or use ultraviolet light to irradiate to kill residual pathogens.
  • ultraviolet light refers to "Far-UVC light: A new tool to control the spread of airborne-mediated microbial diseases” Scientific RePortS
  • influenza research community has begun to investigate the viral genes and biology that drive viral transmission through aerosols or mammalian respiratory droplets.
  • Influenza detection is mainly based on Hemoglutin antigen, so H1-H16 Aptamer can be used to make sensor chip 14. Basically, as long as each H-type antigen is made separately, or six-in-one, as long as three types are produced, it can be covered All influenza virus species and variant combinations. As shown in FIG.
  • it is a two-in-one sensing chip, including two working electrodes 61, two counter electrodes 63, sharing a reference electrode 65, and setting aptamers for two different H-type antigens, such as for H1, and H3 Subtype influenza virus; or a three-in-one sensor chip with aptamers of three different H-type antigens, such as H1, H2 and H3 subtype influenza viruses; or H5, H7 and H9 subtype zoonotic influenza viruses .
  • H1 H3, H5, H9; or in the six-in-one sensor chip, set six different H-type antigen aptamers, such as H1, H2 and H3 subtype influenza virus, H5, Zoonotic influenza viruses of subtypes H7 and H9.
  • the working electrode of the sensing chip 14 was electrochemically treated by cycling the gold working electrode between -0.2 and +1.2 V at 0.1 V/s in 0.5 M H 2 SO 4 until reproducible cyclic volts were obtained. Antu. Then 0.5 ⁇ M of the thiolated aptamer probe with an oligoethylene glycol spacer (HS-(CH 2 CH 2 O) 18 was added to 100 ⁇ L of phosphate buffered saline (PBS: 10 mM phosphate buffered saline, 5 mM MgCl 2 ) 18 -GGACCAGTTGTCTTTCGGTCTCTACCCCAGCCCGT), pH 7.4, incubated at 95°C for 10 minutes, then cooled to room temperature.
  • PBS 10 mM phosphate buffered saline, 5 mM MgCl 2
  • pH 7.4 pH 7.4
  • the HS-A20S solution was mixed with 1 ⁇ L of tris-(2-carboxyethyl)phosphine hydrochloride (TCEP) stock solution (100 mM). The mixture was kept for 1 hour to reduce the dithiol bonds. The clean gold electrodes were then immersed in the above solution and kept at room temperature for 12 hours. The electrodes were rinsed with PBS and immersed in aqueous MCH (1 mM) for 4 h. The functionalized electrodes were rinsed thoroughly with PBS 3 times before use.
  • TCEP tris-(2-carboxyethyl)phosphine hydrochloride
  • SARS-CoV-2 Structure of SARS-CoV-2; consists of a spike protein; it includes two regions, S1 and S2, where S1 is used for host cell receptor binding and S2 is used for membrane fusion. Spike proteins are typical targets for neutralization with antibodies and vaccines. SARS-CoV-2 has been reported to infect human respiratory epithelial cells 100-1000 times faster than previous coronavirus strains and by interacting with the human ACE2 receptor.
  • Nucleocapsid protein is the most abundant protein in SARS-CoV-2.
  • the N protein is a highly immunogenic phosphoprotein that rarely changes.
  • the N protein of SARS-CoV-2 is often used as a marker in diagnostic assays.
  • IgG antibodies can confirm persistent, even past infection, IgA antibodies have been described as an early marker of acute respiratory infection. In a recent study (Okba et al., doi: 10.1101/2020.03.18.20038059; March 2020), the added value of specific IgA detection for the early diagnosis of acute SARS-CoV-2 infection was demonstrated. Good sensitivity and specificity of ELISA have also been demonstrated.
  • a self-assembled monolayer (SAM) of MHDA was formed by soaking the gold electrode (Au) in an ethanol solution containing 1 mM 16 MHDA for 24 h. After SAM formation, the Au/MHDA electrodes were treated for 20 min at room temperature in a mixture of 5 mM EDC, 15 mM NHS and PBS solutions to activate the carboxylic acid groups of MHDA. Subsequently, the antibody IgG and IgM of COVID-19 were covalently immobilized on the Au/MHA electrode by incubating the modified electrode in 0.1 M PBS solution (pH 7.4) containing 100 ⁇ g/mL stock solution at 37 °C for about 1 h. superior.
  • PBS solution pH 7.4
  • a 51-nt3 hairpin aptamer for CoV2-RBD-1C (5'-CAGCACCGACCTTGTGCTTTGGGAGTGCTGGTCCAAGGGCGTTAATGGACA-3').
  • the Kd value of this aptamer for RBD was 5.8 ⁇ 0.8 nM.
  • NG-THI-AuNPs nanocomposite uses NG-THI-AuNPs nanocomposite to modify the working electrode.
  • the synthesis process of NG-THI-AuNPs nanocomposite is as follows: a total of 2 mg of NG is mixed with 2 mL of ultrapure water in a round bottom flask, and then sonicated for 30 minutes to form a stable NG solution. After that, 2 mL of THI solution (2 mg/mL) was added to the above flask, followed by vigorous stirring for 24 h. THI molecules will be non-covalently bound to the NG surface due to the ⁇ - ⁇ stacking interaction between the benzene rings. Unintegrated THI molecules were removed by centrifugation and washing several times to obtain NG-THI nanocomposites.
  • the synthesized nanocomposites were then dispersed in 2 mL of water. Then 10 mL of AuNPs solution with a diameter of about 15 nm was added to the above dispersion and stirred overnight to promote the complete integration of AuNPs with the amino groups of NG.
  • AuNPs were prepared according to the literature (Guo and Wang, 2007). Finally, after washing and centrifugation, NG-THI-AuNPs nanocomposites were obtained and stored at 4 °C for further use.
  • the aptamers have been modified with sulfhydryl groups at the 5' end, this facilitates their binding to AuNPs via Au-S bonds.
  • block any non-specific binding sites with 10 ⁇ L of 1 mM MCH solution.
  • the modified aptamer sensor chip was washed 3 times with 1 mL of TE buffer.
  • the prepared aptamer sensing chip can be loaded into the bioaerosol detection device of the present invention when used, and connected to the reading circuit module, using DPV to measure the concentration of SARS-CoV-2 virus in the PB solution, and inversely calculate The concentration of SARS-CoV-2 virus in the air.
  • Example 4 SARS virus sensor.
  • aptamers specific for the nucleocapsid protein of SARS virus please refer to Korean Patent KR20120139512, or Cho, S.J., Woo, H.M., Kim, K.S., Oh, J.W., and Jeong, Y.J. (2011) .Novel system for detecting SARS coronavirus nucleocapsid protein using an ssDNA aptamer.J.Biosci.Bioeng.112,535–540. Two proposed DNA aptamers, the first
  • the 5' end was modified with a thiol on the 6-position carbon linker
  • the fabrication of the sensing chip and the EIS measurement can refer to Example 1.
  • Norovirus or Calicivirus
  • Calicivirus is the most common cause of viral gastroenteritis, also known as winter vomiting sickness.
  • the annual outbreak keeps hundreds of staff and tens of thousands of patients out of work for days and shuts down entire wards in hospitals in developed countries around the world.
  • PB-PEDOT-AuNPs nanocomposite uses PB-PEDOT-AuNPs nanocomposite to modify the working electrode.
  • the synthesis procedure of PB-PEDOT-AuNPs nanocomposite is as follows.
  • PB-PEDOT nanocomposite is synthesized by oxidative polymerization of EDOT in the presence of Fe3+ ions .
  • the PB-PEDOT nanocomposite has a core-shell structure, which can significantly improve the stability and conductivity of PB. Briefly, 50 ⁇ L of EDOT was first dissolved in 5 mL of ethanolic solution and then transferred to 25 mL of 0.1 M HCl to form a stable solution.
  • the aptamers have been modified with sulfhydryl groups at the 5' end, this facilitates their binding to AuNPs via Au-S bonds.
  • block any non-specific binding sites with 10 ⁇ L of 1 mM MCH solution.
  • the modified aptamer sensor chips were washed 3 times with 1 mL of TE buffer.
  • the prepared aptamer sensing chip can be loaded into the bioaerosol detection device of the present invention when used, and connected to the reading circuit module, using DPV to measure the concentration of SARS-CoV-2 virus in the PB solution, and inversely calculate The concentration of SARS-CoV-2 virus in the air.
  • nucleocapsid protein or the virus itself in the air needs to be detected. At least it can be determined that the nucleocapsid protein is not infectious. But it can help determine whether the air is infected by a virus.
  • all infectious pathogens in addition to detecting the number of pathogens themselves, proteins in various parts of the pathogen may be produced in the host's body in the blood, nasal cavity, throat, lungs, etc.
  • An embodiment of the present invention also provides a method for detecting biological aerosols, using the above-mentioned biological aerosol detecting device, including the following steps:
  • Step 1 filter, remove the non-target biological aerosol from the air to be tested;
  • Step 2 air extraction, and the ambient air is sucked into the device by an air intake fan;
  • Step 3 capturing and collecting, impacting the bioaerosol into the oil film/biological buffer in the device, so that the bioaerosol adheres to the oil film, or passes through the oil film and directly enters the biological buffer;
  • Step 4 The biological aerosol is converted into a hydrosol, and the tapered airway of the detection device is used to generate an impact force, or the first pump blows the aerosol captured above the oil film and flips the oil film into the biological buffer to become a hydrosol;
  • Step 5 Concentrating mass transfer, using the design of the circulating flow channel, all the hydrosols in the biological buffer flow to the sensing chip and the detection molecules on the chip are captured and combined;
  • Step 6 Detecting, using the detection molecules on the sensing chip to capture and combine, and the resulting signal changes to detect the concentration of the target biological aerosol.
  • first and second are only used for descriptive purposes, and should not be construed as indicating or implying relative importance or implying the number of indicated technical features. Thus, a feature defined as “first” or “second” may expressly or implicitly include one or more of that feature.
  • “plurality” means two or more, unless otherwise expressly and specifically defined.
  • the terms “installed”, “connected”, “connected”, “fixed” and other terms should be understood in a broad sense, for example, it may be a fixed connection or a detachable connection , or integrated; it can be a mechanical connection or an electrical connection; it can be a direct connection or an indirect connection through an intermediate medium, and it can be the internal connection of the two elements or the interaction relationship between the two elements.
  • installed may be a fixed connection or a detachable connection , or integrated; it can be a mechanical connection or an electrical connection; it can be a direct connection or an indirect connection through an intermediate medium, and it can be the internal connection of the two elements or the interaction relationship between the two elements.
  • a first feature "on” or “under” a second feature may include the first and second features in direct contact, or may include the first and second features Not directly but through additional features between them.
  • the first feature being “above”, “over” and “above” the second feature includes the first feature being directly above and obliquely above the second feature, or simply means that the first feature is level higher than the second feature.
  • the first feature is “below”, “below” and “below” the second feature includes the first feature being directly below and diagonally below the second feature, or simply means that the first feature has a lower level than the second feature.

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Abstract

A bioaerosol detection device, comprising a collection module, a detection module, and a power supply. The collection module comprises an air extraction fan (11), an arc-shaped tapered air passage, a first pump (24), an oil-water container, and a second pump (27); an oil layer and a biological buffer solution (35) are provided in the oil-water container; a filter unit (10) is provided at the air inlet of the air extraction fan (11) to preliminarily filter the air extracted and generate impact force by means of the arc-shaped tapered airway to collect bioaerosols in the air to above the oil layer of the oil-water container; the detection module comprises a sensing chip (14) unit, a signal processing unit, and a microcontroller (17) unit, and these units are electrically connected to each other; at least one detection molecule (53) is attached on the sensing chip (14) unit to detect specific bioaerosols entering the biological buffer solution (35); and the power supply supplies the power required by the collection module and the detection module. The present application also provides a bioaerosol detection method, and is used for addressing incompatibilities between air sampling and liquid-based sensing technology.

Description

一种生物气溶胶检测装置A bioaerosol detection device 技术领域technical field
本发明涉及生物气溶胶检测技术领域,特别涉及一种生物气溶胶检测装置。The invention relates to the technical field of biological aerosol detection, in particular to a biological aerosol detection device.
背景技术Background technique
已知有几种病原体通过人与人之间的空气传播,包括病毒如流感(flu)、冠状病毒(coronavirus)例如SARS、MERS、COVID-19、水痘(chicken pox)和罗露拉菌rubeola(麻疹)、诺罗病毒(Norovirus)、或杯状病毒(Calicivirus)、以及细菌如结核分枝杆菌(tuberculosis)、博德特氏菌百日咳(whooping cough)、和耐甲氧西林金黄色葡萄球菌(如肺炎)。这些空气传播的病原体可以在固体颗粒上传播,如灰尘和皮肤薄片,或通过呼吸,说话,咳嗽,打喷嚏,呕吐等产生的气溶胶雾滴。Several pathogens are known to spread through the air from person to person, including viruses such as influenza, coronaviruses such as SARS, MERS, COVID-19, chicken pox, and rubeola ( measles), Norovirus, or Calicivirus, and bacteria such as tuberculosis, Bordetella whooping cough, and methicillin-resistant Staphylococcus aureus ( such as pneumonia). These airborne pathogens can be spread on solid particles, such as dust and skin flakes, or through aerosol droplets produced by breathing, talking, coughing, sneezing, vomiting, etc.
还有从感染者以外的其他来源传播的空气传播病原体,如细菌和真菌孢子(fungi),鸟粪中的细菌或空调等基于液体的系统。还发现冲洗厕所产生含病原体的气溶胶。当人类暴露于处在此类病原体的环境中时,存在空气传播感染的风险。此外,某些季节中,在空气传播的花粉也会引发某些人的过敏反应。There are also airborne pathogens that spread from sources other than infected people, such as bacterial and fungal spores (fungi), bacteria in bird droppings, or liquid-based systems such as air conditioners. Flushing toilets has also been found to produce pathogen-laden aerosols. There is a risk of airborne infection when humans are exposed to such pathogens. Additionally, airborne pollen can trigger allergic reactions in some people during certain seasons.
用于生物气溶胶的三种最常见的有效采样方法是过滤(filters),冲击器(impactors)和撞击器(impingers)。撞击器(impingers)是基于液体收集的采样器,依赖于5mL或20mL的工作体积,而过滤器和冲击器是基于干燥采集的采样器,依赖于洗脱步骤从各自的固体支持物中提取收集的病毒。该洗脱可导致最终提取的样品体积大,通常为几毫升。如果在采样的空气体积中仅存在少量病毒颗粒,则这些大体积产生巨大的稀释,使得这些方法不适合于低检测限(LoD)测量。此外,从撞击器,过滤器或冲击器到生物传感器的液体体积的处理和处理的集成和自动化需要大量的系统复杂性,不适合就地照护点(PoC)应用。The three most common effective sampling methods for bioaerosols are filters, impactors and impingers. Impingers are liquid collection-based samplers that rely on a 5mL or 20mL working volume, while filters and impingers are dry-collection-based samplers that rely on elution steps to extract the collection from their respective solid supports virus. This elution can result in a large final extracted sample volume, typically several milliliters. If only a small number of viral particles are present in the sampled air volume, these large volumes produce huge dilutions, making these methods unsuitable for low limit of detection (LoD) measurements. Furthermore, the integration and automation of handling and processing of liquid volumes from impactors, filters or impactors to biosensors requires significant system complexity and is not suitable for point-of-care (PoC) applications.
另外,也有些应用使用BioSamplers(SKC Inc.)搭配220伏SKC BioLite取样泵(SKC Inc.)进行生物气溶胶取样。简而言之,将采样器连接到在线蒸汽疏水阀(SKC Inc.)以保护泵免受潮湿,并且允许泵运行5分钟暖身,然后采样。用含有0.5%(w/v)牛血清白蛋白级分V(BSA)粉末的15ml无菌磷酸盐缓冲盐水(PBS)填充SKC BioSampler,并置于离地面1-1.5m处。每个采样泵以8/l/min的流速运行30分钟,允许每个站点采样约240升空气。在采样期结束时,关闭泵,将BioSampler断开,并将样品培养基从SKC Bio-Sampler收集容器无菌转移到无菌的15ml锥形管中。送去进行定量聚合酶链反应(qPCR)。所有采样器在每个采样日结束时用高压灭菌器消毒。In addition, there are some applications using BioSamplers (SKC Inc.) with a 220V SKC BioLite Sampling Pump (SKC Inc.) for bioaerosol sampling. Briefly, the sampler was connected to an in-line steam trap (SKC Inc.) to protect the pump from moisture, and the pump was allowed to run for 5 minutes to warm up before sampling. The SKC BioSampler was filled with 15 ml sterile phosphate buffered saline (PBS) containing 0.5% (w/v) bovine serum albumin fraction V (BSA) powder and placed 1-1.5 m above the ground. Each sampling pump was run for 30 minutes at a flow rate of 8/l/min, allowing approximately 240 liters of air to be sampled per site. At the end of the sampling period, the pump was turned off, the BioSampler was disconnected, and the sample medium was aseptically transferred from the SKC Bio-Sampler collection container to a sterile 15 ml conical tube. Sent for quantitative polymerase chain reaction (qPCR). All samplers were autoclaved at the end of each sampling day.
此外市面上也有一些系统包括一个定制的静电沉淀(ESP)为基础的生物气溶胶采样器,与下游定量聚合酶链反应(qPCR)分析相结合。将雾化的病毒直接取样到液体体积为150 μL的小型化收集器中,这构成了随后的生物测定的简单且直接的界面。与其他基于液体的生物气溶胶采样器相比,该方法将样品稀释减少了至少一个数量级。There are also systems on the market that include a custom electrostatic precipitation (ESP)-based bioaerosol sampler combined with downstream quantitative polymerase chain reaction (qPCR) analysis. The aerosolized virus was sampled directly into a miniaturized collector with a liquid volume of 150 μL, which constituted a simple and straightforward interface for subsequent bioassays. This method reduces sample dilution by at least an order of magnitude compared to other liquid-based bioaerosol samplers.
上面介绍的生物气溶胶的常用取样方法依赖于捕获颗粒的实验室分析。目前没有已建立的方法在采样点提供敏感的检测,识别和量化。然而,在靠近病人的就地照护点(PoC)或在医疗保健和其他设施中进行空气监测时,敏感和直接检测空气传播病原体可能有助于快速诊断,疾病扩散和预防爆发,以及清洗受污染的设施后,达成立即性的生物气溶胶控制。Common sampling methods for bioaerosols described above rely on laboratory analysis of captured particles. There are currently no established methods that provide sensitive detection, identification and quantification at the sampling point. However, sensitive and direct detection of airborne pathogens may aid in rapid diagnosis, disease spread and prevention of outbreaks, as well as in cleaning contaminated air when air monitoring is performed near the patient's point-of-care (PoC) or in healthcare and other facilities After installation, immediate bioaerosol control is achieved.
为解决上述生物气溶胶收集与就地感测分开的事实,就地感测的装置,似乎可以将生物传感器结合于生物气溶胶收集器的后端,来达到POC的检测目标。但是,现在的多功能工具例如Lab on a chip(LoC)生物传感器仅适用于液体样品。为了让检测和分析空气传播颗粒(如生物气溶胶)有相同的多样可能性,必须开发兼容空气取样和空气-液体界接技术。另外,取样后能连接可以立即进行在地检测的芯片,需要精准与实时兼顾。为了解决空气取样和基于液体的感测技术的不兼容问题,跨学科方法有其必要,本发明即在于解决此问题。In order to solve the above-mentioned fact that bioaerosol collection is separated from in situ sensing, the in situ sensing device seems to be able to combine the biosensor with the back end of the bioaerosol collector to achieve the detection goal of POC. However, current multifunctional tools such as Lab on a chip (LoC) biosensors are only suitable for liquid samples. In order to have the same diversity of possibilities for the detection and analysis of airborne particles, such as bioaerosols, compatible air sampling and air-liquid interface technologies must be developed. In addition, after sampling, it is possible to connect to a chip that can perform on-site detection immediately, which requires both precision and real-time. To address the incompatibility of air sampling and liquid-based sensing technologies, an interdisciplinary approach is necessary, and the present invention addresses this issue.
发明内容SUMMARY OF THE INVENTION
本发明旨在至少在一定程度上解决上述技术中的技术问题之一。为此,本发明的一个目的在于提出一种生物气溶胶检测装置,解决空气取样和基于液体的感测技术的不兼容问题。The present invention aims to solve one of the technical problems in the above technologies at least to a certain extent. To this end, one object of the present invention is to propose a bioaerosol detection device that solves the incompatibility problem of air sampling and liquid-based sensing technologies.
本发明的第二个目的在于提出一种生物气溶胶检测的方法,解决空气取样和基于液体的感测技术的不兼容问题。The second object of the present invention is to propose a method for bioaerosol detection, which solves the incompatibility problem of air sampling and liquid-based sensing technology.
为达到上述目的,本发明实施例一方面提出了一种生物气溶胶检测装置,包括:In order to achieve the above purpose, one aspect of the embodiments of the present invention provides a bioaerosol detection device, including:
收集模块,收集模块包括抽气风扇、弧形渐缩气道、第一泵浦、油水容器、第二泵浦;油水容器内设置有油层及生物缓冲液;抽气风扇进气口设置过滤单元,以将吸入空气初步过滤,并经由该弧形渐缩气道产生冲击力将空气中的生物气溶胶收集到油水容器的油层上方,让生物气溶胶吸附于油层表面,然后定时透过第一泵浦将压力风打在油层表面上,使油层翻转,在翻转过程,待测生物气溶胶翻转至油层下,进入生物缓冲液中;Collection module, the collection module includes a suction fan, an arc-shaped tapered air passage, a first pump, an oil-water container, and a second pump; the oil-water container is provided with an oil layer and a biological buffer; the air inlet of the suction fan is provided with a filter unit , to preliminarily filter the inhaled air, and generate impact force through the arc-shaped tapered airway to collect the bio-aerosol in the air above the oil layer of the oil-water container, so that the bio-aerosol is adsorbed on the surface of the oil layer, and then periodically passes through the first The pump hits the pressure air on the surface of the oil layer to turn the oil layer. During the inversion process, the bioaerosol to be tested is turned under the oil layer and enters the biological buffer;
检测模块,检测模块包括感测芯片单元、讯号处理单元、微控制器单元,各单元电性相连;感测芯片单元上固着至少一探测分子,以检测进入生物缓冲液中特定的生物气溶胶;a detection module, the detection module includes a sensing chip unit, a signal processing unit, and a microcontroller unit, and each unit is electrically connected; at least one detection molecule is fixed on the sensing chip unit to detect a specific biological aerosol entering the biological buffer;
电源,电源供应收集模块与检测模块所需电力;Power supply, the power supply the power required by the collection module and the detection module;
其中进入生物缓冲液中的待测生物气溶胶,经由循环的流道设计,配合第二泵浦的驱动,让油层下的生物缓冲液及待测生物气溶胶都会循环流经感测芯片单元,使待测生物气溶胶有效接触探测分子,达成捕捉与检测。The bioaerosol to be tested entering the biological buffer solution is designed with a circulating flow channel and driven by the second pump, so that the biological buffer solution and the bioaerosol to be tested under the oil layer will circulate through the sensing chip unit. The bioaerosol to be tested is effectively contacted with the detection molecules to achieve capture and detection.
根据本发明实施例的一种生物气溶胶检测装置,进入生物缓冲液中的待测生物气溶胶,经由循环的流道设计,配合第二泵浦的驱动,让油层下的生物缓冲液及待测生物气溶胶都会循环流经感测芯片单元,使待测生物气溶胶有效接触适体或抗体,达成捕捉与检测,从而解决空气取样和基于液体的感测技术的不兼容问题。According to a bioaerosol detection device according to an embodiment of the present invention, the bioaerosol to be tested entering the biological buffer solution is designed with a circulating flow channel and driven by the second pump, so that the biological buffer solution under the oil layer and the waiting The bioaerosols to be measured will circulate through the sensor chip unit, so that the bioaerosols to be measured can effectively contact aptamers or antibodies to achieve capture and detection, thereby solving the incompatibility between air sampling and liquid-based sensing technologies.
另外,根据本发明上述实施例提出的一种生物气溶胶检测装置,还可以具有如下附加的技术特征:In addition, the bioaerosol detection device proposed according to the above embodiments of the present invention may also have the following additional technical features:
进一步,生物气溶胶包括病毒、病菌、真菌(fungi)、花粉至少其中之一。Further, the bioaerosol includes at least one of viruses, germs, fungi, and pollen.
进一步,检测模块包括无线通讯模块或显示单元。Further, the detection module includes a wireless communication module or a display unit.
进一步,生物缓冲液内含氧化还原离子选自赤血盐、黄血盐、六氨合钌、酵素。Further, the redox ions contained in the biological buffer are selected from red blood salt, yellow blood salt, ruthenium hexaammine, and enzymes.
进一步,探测分子选自适体、抗体或醣分子。Further, the probe molecules are selected from aptamers, antibodies or carbohydrate molecules.
进一步,感测芯片上添加用于捕获目标物的适体或抗体使用的纳米材料,纳米材料选自纳米磁珠、纳米金、碳管、石墨烯、ZnO,以及这些纳米材料进一步结合硫氨酸或普鲁士蓝。Further, nanomaterials used for aptamers or antibodies for capturing the target are added on the sensing chip, and the nanomaterials are selected from nanomagnetic beads, nanogold, carbon tubes, graphene, ZnO, and these nanomaterials are further combined with thionine or Prussian blue.
进一步,感测芯片单元的检测方式为光学法,选自表面等离振子法,比色法,化学发光法,荧光法,表面增强拉曼散射法和干涉法。Further, the detection method of the sensing chip unit is an optical method selected from surface plasmon method, colorimetric method, chemiluminescence method, fluorescence method, surface enhanced Raman scattering method and interference method.
进一步,感测芯片单元的检测方式为电学法,当目标物与抗体或适体之间的结合引起或改变电信号时,即可侦测目标物的浓度,选自电学法,压电换能器法,场效晶体管法,纳米孔。Further, the detection method of the sensing chip unit is an electrical method. When the binding between the target and the antibody or aptamer causes or changes an electrical signal, the concentration of the target can be detected. device method, field effect transistor method, nanopore.
进一步,电学法的讯号处理单元主要选自安培法、方波伏安法、差式脉波伏安法、计时安培法、间歇脉冲安培法、快速扫描循环伏安法、电化学阻抗频谱法、场效应酶检测法或其组合。Further, the signal processing unit of the electrical method is mainly selected from amperometric method, square wave voltammetry, differential pulse wave voltammetry, chronoamperometry, intermittent pulse amperometric method, fast scanning cyclic voltammetry, electrochemical impedance spectroscopy, Field-effect enzyme assays or combinations thereof.
为达到上述目的,本发明实施例第二方面提出了一种生物气溶胶检测的方法,使用上述生物气溶胶检测装置,包括以下步骤:In order to achieve the above purpose, a second aspect of the embodiments of the present invention provides a method for detecting biological aerosols, using the above-mentioned biological aerosol detecting device, including the following steps:
步骤一、过滤,将通过的待测空气去除非目标生物气溶胶; Step 1, filter, remove the non-target biological aerosol from the air to be tested;
步骤二、抽气,将环境空气利用进气风扇吸入装置;Step 2, air extraction, and the ambient air is sucked into the device by an air intake fan;
步骤三、捕捉收集,将生物气溶胶冲击至装置内油膜/生物缓冲液,让生物气溶胶附着油膜,或是穿越油膜,直接进入生物缓冲液中;Step 3, capturing and collecting, impacting the bioaerosol into the oil film/biological buffer in the device, so that the bioaerosol adheres to the oil film, or passes through the oil film and directly enters the biological buffer;
步骤四、生物气溶胶转水溶胶,利用检测装置的渐缩气道产生冲击力,或是第一泵浦吹开油膜翻转油膜上方捕捉的气溶胶至生物缓冲液中,变成水溶胶;Step 4: The biological aerosol is converted into a hydrosol, and the tapered airway of the detection device is used to generate an impact force, or the first pump blows the aerosol captured above the oil film and flips the oil film into the biological buffer to become a hydrosol;
步骤五、浓缩质传,利用循环流道的设计,将生物缓冲液内的水溶胶全数流动到感测芯片与芯片上的探测分子捕捉结合;Step 5: Concentrating mass transfer, using the design of the circulating flow channel, all the hydrosols in the biological buffer flow to the sensing chip and the detection molecules on the chip are captured and combined;
步骤六、检测,利用感测芯片上的探测分子捕捉结合,产生的讯号改变,进行目标生 物气溶胶的浓度侦测。The sixth step, detection, utilizes the detection molecules on the sensing chip to capture and bind, and the resulting signal changes to detect the concentration of the target bioaerosol.
附图说明Description of drawings
图1为根据本发明实施例的生物气溶胶检测模块的功能方块图;1 is a functional block diagram of a bioaerosol detection module according to an embodiment of the present invention;
图2A为根据本发明实施例的生物气溶胶检测装置的内部结构示意图;2A is a schematic diagram of the internal structure of a bioaerosol detection device according to an embodiment of the present invention;
图2B为根据本发明实施例的生物气溶胶检测装置的立体结构示意图;2B is a schematic three-dimensional structure diagram of a bioaerosol detection device according to an embodiment of the present invention;
图3为根据本发明实施例的生物气溶胶检测装置的进气与出气的气流方向示意图;FIG. 3 is a schematic diagram of the air flow directions of the air intake and the air outlet of the bioaerosol detection device according to an embodiment of the present invention;
图4A为根据本发明实施例的生物气溶胶检测装置的进气风扇、第一泵浦、第二泵浦配置图;4A is a configuration diagram of an intake fan, a first pump, and a second pump of a bioaerosol detection device according to an embodiment of the present invention;
图4B为根据本发明实施例的生物气溶胶检测装置的图4A的1/4剖面图;4B is a 1/4 sectional view of FIG. 4A of the bioaerosol detection device according to an embodiment of the present invention;
图4C为根据本发明实施例的生物气溶胶检测装置的第一泵浦作动气流方向示意图;4C is a schematic diagram of the flow direction of the first pump actuation of the bioaerosol detection device according to an embodiment of the present invention;
图5A为根据本发明实施例的生物气溶胶检测装置的第二泵浦作动水流方向示意图;5A is a schematic diagram of the flow direction of the second pump actuation water flow of the bioaerosol detection device according to an embodiment of the present invention;
图5B为根据本发明实施例的生物气溶胶检测装置的第二泵浦作动水流方向示意图;5B is a schematic diagram of the flow direction of the second pump actuation water flow of the bioaerosol detection device according to an embodiment of the present invention;
图5C为根据本发明实施例的生物气溶胶检测装置的第二泵浦未作动的待测生物气溶胶分布示意图;5C is a schematic diagram of the distribution of the bioaerosol to be measured when the second pump of the bioaerosol detection device according to the embodiment of the present invention is not actuated;
图5D为根据本发明实施例的生物气溶胶检测装置的第二泵浦作动的待测生物气溶胶分布示意图;5D is a schematic diagram of the distribution of the bioaerosol to be detected in the second pumping action of the bioaerosol detection device according to the embodiment of the present invention;
图6为根据本发明实施例的生物气溶胶检测装置的感测芯片结构示意图;6 is a schematic structural diagram of a sensing chip of a bioaerosol detection device according to an embodiment of the present invention;
图7为根据本发明实施例的生物气溶胶检测装置实施例的场效应酶感测平台的示意图;7 is a schematic diagram of a field-effect enzyme sensing platform of an embodiment of a bioaerosol detection device according to an embodiment of the present invention;
图8为根据本发明实施例的生物气溶胶检测装置实施例的场效应酶感测芯片结构示意图。FIG. 8 is a schematic structural diagram of a field-effect enzyme sensing chip of an embodiment of a bioaerosol detection device according to an embodiment of the present invention.
标号说明Label description
生物气溶胶检测装置1     环境空气5 Bioaerosol Detection Device 1 Ambient Air 5
过滤单元10              抽气风扇11 Filter unit 10 Exhaust fan 11
油膜/生物缓冲液容器13   感测芯片14Oil film/biological buffer container 13 Sensing chip 14
讯号读取模块16          微控制器17 Signal reading module 16 Microcontroller 17
无线通讯模块18          电源供应模块19 Wireless communication module 18 Power supply module 19
第一泵浦24              第二泵浦27First pump 24 Second pump 27
底座28                  上盖29 Base 28 Cover 29
油膜33                  生物缓冲液35 Oil Film 33 Biological Buffer 35
病毒51                  探测分子53 Virus 51 Detector molecule 53
循环水路55              水流方向57Circulating waterway 55 The direction of water flow 57
工作电极61              反电极63Working electrode 61 Counter electrode 63
参考电极65              适体/酵素结合体71 Reference electrode 65 aptamer/enzyme conjugate 71
第一适体711             酵素712The first aptamer 711 Enzyme 712
病菌或病毒72            第二适体73Bacteria or virus72 Second aptamer73
门控电压74              Gating电极GE75。 Gating voltage 74 Gating electrode GE75.
具体实施方式Detailed ways
下面详细描述本发明的实施例,所述实施例的示例在附图中示出,其中自始至终相同或类似的标号表示相同或类似的元件或具有相同或类似功能的元件。下面通过参考附图描述的实施例是示例性的,旨在用于解释本发明,而不能理解为对本发明的限制。The following describes in detail the embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein the same or similar reference numerals refer to the same or similar elements or elements having the same or similar functions throughout. The embodiments described below with reference to the accompanying drawings are exemplary, and are intended to explain the present invention and should not be construed as limiting the present invention.
本发明的生物气溶胶检测模块1主要须达到三个目标,如图1、图2A、图2B及图3所示,第一、在一般环境下,可能含有生物气溶胶的环境空气5由抽气风扇11被抽入经过过滤单元10将被测生物气溶胶纯化,被测生物气溶胶不会受到过滤方式影响其表面生化特性。第二、透过弧形渐缩气道的设计,流速与压力的参数调整,产生冲击力将空气中的生物气溶胶打入油膜/生物缓冲液容器13的油膜33上方,让生物气溶胶吸附于油膜33表面,然后定时透过第一泵浦24将压力风打在油膜33表面上,使油膜33翻转,在翻转过程,待测生物气溶胶会翻转至油膜33下,进入生物缓冲液35中;第三、进入生物缓冲液35中的待测生物气溶胶,经由特殊的流道设计,配合第二泵浦27的驱动,让油膜33下的生物缓冲液35及待测生物气溶胶都会循环流经感测芯片14,使待测生物气溶胶有效接触专一性的适体或抗体,达成接近百分百的捕捉与检测。其中,生物缓冲液35可以是磷酸盐缓冲生理盐水(Phosphate-buffered saline,PBS)。The bioaerosol detection module 1 of the present invention mainly needs to achieve three goals, as shown in FIG. 1 , FIG. 2A , FIG. 2B and FIG. 3 , first, in a general environment, the ambient air 5 that may contain bioaerosols is extracted by The air fan 11 is drawn into the filter unit 10 to purify the bio-aerosol to be tested, and the bio-aerosol to be tested will not be affected by the filtering method on its surface biochemical properties. Second, through the design of the arc-shaped tapered airway, the parameters of the flow rate and pressure are adjusted to generate an impact force to push the bioaerosol in the air into the oil film 33 of the oil film/biological buffer container 13, so that the bioaerosol can be adsorbed On the surface of the oil film 33, and then the pressure wind is periodically hit on the surface of the oil film 33 through the first pump 24, so that the oil film 33 is turned over. 3. The biological aerosol to be tested entering the biological buffer 35 is driven by the second pump 27 through a special flow channel design, so that the biological buffer 35 under the oil film 33 and the biological aerosol to be tested will be Circulating flow through the sensing chip 14 makes the bioaerosol to be tested effectively contact with the specific aptamer or antibody, so as to achieve nearly 100% capture and detection. Wherein, the biological buffer 35 may be Phosphate-buffered saline (Phosphate-buffered saline, PBS).
本示例中,第一泵浦24采用小型泵浦,第二泵浦为蠕动泵浦。In this example, the first pump 24 is a small pump, and the second pump is a peristaltic pump.
需要注意的是,PBS这样的生物缓冲液是可以有更多的选择,只要该生物缓冲液(亦称为Good's Buffers)于某些对pH值较为敏感的生化反应中有重要作用,使用这类化学品有助于调控并维持反应环境的pH值于生理pH范围。来源可以取自Hopax这家全球最大的Good's Buffers制造商之一。Good's Buffers具有以下特点:pKa值介于6和8之间、水溶性佳、不具毒性,不易对生化反应产生干扰、不易通透细胞膜、对酵素和水解稳定性佳、不易随环境温度变化而改变,以及与矿质阳离子的交互作用有限。It should be noted that there are more choices for biological buffers such as PBS, as long as the biological buffer (also known as Good's Buffers) plays an important role in some biochemical reactions that are more sensitive to pH, use this kind of buffer. Chemicals help to regulate and maintain the pH of the reaction environment within the physiological pH range. The source can be taken from Hopax, one of the largest manufacturers of Good's Buffers in the world. Good's Buffers have the following characteristics: pKa value between 6 and 8, good water solubility, non-toxic, not easy to interfere with biochemical reactions, not easy to penetrate cell membranes, good stability to enzymes and hydrolysis, not easy to change with environmental temperature changes , and limited interaction with mineral cations.
图2A为根据本发明实施例的生物气溶胶检测装置的内部结构示意图,图2B为根据本发明实施例的生物气溶胶检测装置的立体结构示意图,该生物气溶胶检测装置包括底座28、上盖29、抽气风扇11、第一泵浦24、感测芯片14及第二泵浦27,抽气风扇11、第一泵浦24、感测芯片14、第二泵浦27设置在底座上,上盖29罩设在底座28上。2A is a schematic diagram of the internal structure of a bio-aerosol detection device according to an embodiment of the present invention, and FIG. 2B is a schematic diagram of a three-dimensional structure of a bio-aerosol detection device according to an embodiment of the present invention. The bio-aerosol detection device includes a base 28 and an upper cover. 29. The suction fan 11, the first pump 24, the sensing chip 14 and the second pump 27, the suction fan 11, the first pump 24, the sensing chip 14, and the second pump 27 are arranged on the base, The upper cover 29 is covered on the base 28 .
过滤单元10的方式较佳实施例分别为两层,第一层为过滤空气中较大的灰尘颗粒,大颗粒的过滤物为一般肉眼可见的灰尘、沙粒其大小约为数百微米以上的颗粒,使用一般市售的滤棉进行第一层过滤,第二层过滤为过滤空气中的微细颗粒,微细颗粒为粉尘、尘螨 或花粉等数微米至数十微米大小的颗粒,若以受检对象为病菌,其尺寸约为1-2um;或流感病毒,其尺寸约为80-120nm,为达到检测的精确性,方法就是采用适合的过滤装置,由于本发明方向为捕捉空气中的病菌或流感病毒,然而病菌或流感病毒在空气中可能不伴随着水珠,因此必须在芯片表面上提供干燥转换成湿润的机制,以利病菌或病毒透过该机制进而加速病菌或流感病毒与感测芯片表面的适体结合,如图1所示,本发明使用抽气风扇11、过滤单元10,其中,过滤单元10内可以设置两过滤装置,感测芯片14、讯号读取模块16进行生物气溶胶的感测,微控制器17进行调整控制,无线通讯模块18具有通讯功能,电源供应模块19对抽气风扇11、感测芯片14及讯号读取模块16进行供电。The preferred embodiment of the filter unit 10 is two layers, the first layer is to filter the larger dust particles in the air, and the filter of the large particles is generally visible to the naked eye. For particles, use commercially available filter cotton for the first layer of filtration, and the second layer of filtration to filter fine particles in the air. The test object is a germ, and its size is about 1-2um; or an influenza virus, its size is about 80-120nm, in order to achieve the accuracy of detection, the method is to use a suitable filter device, because the direction of the present invention is to capture the germs in the air Or influenza virus, however, the bacteria or influenza virus may not be accompanied by water droplets in the air, so a dry-to-wet mechanism must be provided on the surface of the chip, so that the bacteria or virus can pass through this mechanism to accelerate the bacteria or influenza virus and infection. To measure the aptamer binding on the surface of the chip, as shown in FIG. 1, the present invention uses an exhaust fan 11 and a filter unit 10, wherein two filter devices can be set in the filter unit 10, the sensor chip 14 and the signal reading module 16 perform biological For aerosol sensing, the microcontroller 17 performs adjustment and control, the wireless communication module 18 has a communication function, and the power supply module 19 supplies power to the exhaust fan 11 , the sensing chip 14 and the signal reading module 16 .
如图3、图4A、图4B及图4C所示,本发明主要利用抽气风扇11将环境空气产生强制对流,使环境空气更有效率地进入此检测装置,空气进入设计风道后会接触油膜33,其大部分微生物或病毒会在此沾附于油膜33表面,为使油膜33表面微生物或病毒穿过油膜33与PBS35接触,油膜33上方需有强正压吹下,使油膜33进行翻转,如图4A、图4B、图4C所示,此处利用第一泵浦(small pump)24将强正压从上方进气使得油膜33可以进行翻转,此处使用油膜33的目的是要让PBS长时间处于开放空间中,不会挥发而减少其容积,进而影响待测目标的检测精准度,油膜33较佳的实施例为各类的矿物油、色拉油,或其他不会杀死生物气溶胶的油,也不会与PBS或其添加物,如赤血盐/黄血盐,或其他氧化还原离子(redox)反应,可以维持数个月不会有太多挥发。这个创新的方法,可以免除自动给水装置补充PBS于容器内,使油膜/PBS的厚度维持在固定的容积以内,同时确保PBS或其添加物的浓度维持接近恒定。油膜33的厚度设计在0.1mm到3mm,较佳的范围为0.5mm-1mm。油膜33的厚度要足够,才能让吹开油膜33进行翻转完毕,快速(例如0.5秒到5秒内)恢复油膜33的完整覆盖PBS。As shown in FIG. 3, FIG. 4A, FIG. 4B and FIG. 4C, the present invention mainly uses the exhaust fan 11 to generate forced convection of the ambient air, so that the ambient air can enter the detection device more efficiently, and the air will contact the designed air duct after entering. The oil film 33, most of the microorganisms or viruses will be attached to the surface of the oil film 33. In order for the microorganisms or viruses on the oil film 33 to pass through the oil film 33 and contact with the PBS 35, a strong positive pressure is required above the oil film 33 to blow down the oil film 33. Turn over, as shown in Figure 4A, Figure 4B, Figure 4C, where the first small pump (small pump) 24 is used to inhale the strong positive pressure from above, so that the oil film 33 can be turned over. The purpose of using the oil film 33 here is to Let the PBS stay in the open space for a long time, and it will not volatilize and reduce its volume, thereby affecting the detection accuracy of the target to be measured. The preferred embodiment of the oil film 33 is various types of mineral oil, salad oil, or other substances that will not kill the target. The oil of the bioaerosol also does not react with PBS or its additives, such as red blood salt/yellow blood salt, or other redox ions (redox), and can be maintained for several months without much volatilization. This innovative method eliminates the need for automatic water supply devices to replenish PBS in the container, maintains the thickness of the oil film/PBS within a fixed volume, and ensures that the concentration of PBS or its additives remains nearly constant. The thickness of the oil film 33 is designed in the range of 0.1mm to 3mm, preferably in the range of 0.5mm-1mm. The thickness of the oil film 33 must be sufficient so that the blow-off oil film 33 can be turned over and quickly (eg, within 0.5 seconds to 5 seconds) to restore the complete coverage of the PBS by the oil film 33 .
绝大多数有害于人类或动物的病毒或病菌等病原体为亲水性,所以收集到油膜33上,经过吹气到油膜33上,造成油膜33翻转,让病原体接触PBS,病原体就会亲水进入PBS内,达到有效收集空气中病原体进入PBS内的功效。Most pathogens such as viruses or germs that are harmful to humans or animals are hydrophilic, so they are collected on the oil film 33 and blown onto the oil film 33, causing the oil film 33 to turn over and let the pathogens contact PBS, and the pathogens will enter hydrophilically. In PBS, the effect of effectively collecting airborne pathogens into PBS can be achieved.
在某些实施例中,第一泵浦(small pump)将强正压从上方进气使得油膜33可以进行翻转的功效,也直接由抽气风扇来取代,其方法就是抽气风扇可一大段时间工作于慢速的抽气收集气溶胶于油膜33上,另一段时间工作于高速的抽气,产生强正压同时也将油膜33进行翻转的功效。In some embodiments, the first pump (small pump) has a strong positive pressure to intake air from above, so that the oil film 33 can be turned over, which is also directly replaced by a suction fan. The method is that the suction fan can be large During a period of time, it works at a slow speed to collect aerosols on the oil film 33, and another period of time works at a high speed to generate a strong positive pressure and at the same time, the oil film 33 is turned over.
由于空气中的有害生物气溶胶相对浓度不高,因此传统检测的方法,三种最常见的有效采样方法是过滤,冲击器和撞击器,就是增加收集的机会,并且一旦收集到就加以固定,本发明利用油膜33来收集,该油膜33对于目标物具有吸附作用,但同时也可能将穿过第一道过滤的杂质吸附。因此,当这些目标物与杂质都被翻转进入油膜33下的PBS内,目标生物气溶胶翻转至PBS后,利用第二泵浦27加上封闭循环的循环水路55,如图4A、图4B、 图4C与图5A、图5B所示,使目标生物气溶胶不断在水流方向57中循环,每一次流经感测芯片14就有机会被工作电极上的适体或抗体、或醣分子等探测分子53捕捉,如图5C、图5D所示,流速的调整适当,可以让PBS流动,但不会让已经跟专一性适体或抗体等探针分子结合的目标生物气溶胶脱离。如此一来,基本上PBS内的目标生物气溶胶最终都会与工作电极上的适体专一性的结合,因此透过读取电路的讯号可以定量得知PBS中的目标生物气溶胶浓度。Since the relative concentration of harmful biological aerosols in the air is not high, the traditional detection methods, the three most common effective sampling methods are filtration, impactor and impactor, which increase the chance of collection and fix it once collected, In the present invention, the oil film 33 is used for collection, and the oil film 33 has an adsorption effect on the target, but at the same time, it may also adsorb the impurities passing through the first filter. Therefore, when these targets and impurities are turned over into the PBS under the oil film 33, and the target bioaerosol is turned over to the PBS, the second pump 27 is used to add a closed-loop circulating water circuit 55, as shown in Figure 4A, Figure 4B, As shown in FIG. 4C and FIG. 5A and FIG. 5B, the target bioaerosol is continuously circulated in the water flow direction 57, and each time it flows through the sensing chip 14, there is a chance to be detected by aptamers, antibodies, or sugar molecules on the working electrode. Molecules 53 capture, as shown in Figure 5C and Figure 5D, the flow rate is adjusted properly, PBS can flow, but the target bioaerosol that has been bound to probe molecules such as specific aptamers or antibodies will not be detached. In this way, basically, the target bioaerosol in the PBS will eventually bind specifically to the aptamer on the working electrode. Therefore, the concentration of the target bioaerosol in the PBS can be quantitatively obtained by reading the signal of the circuit.
更具体而言,如图5C所示,目标生物气溶胶例如病毒51非常小,因为扩散的运动方式,属于随机行动,很难有机会移动到工作电极的探测分子53附近,并与该探测分子53结合,也就是浓缩质传乃是必要的手段来提升侦测的灵敏度,如图5D所示,给予溶液很小的循环流动速度,让病毒51的移动成为有方向的移动,特别是垂直朝向工作电极,并且让流速很小,或是流动一段时间,静止一段时间,给予稳定结合的机会,也同时进行讯号量测与处理。More specifically, as shown in Fig. 5C, the target bioaerosol such as virus 51 is very small, and because of the movement mode of diffusion, it is a random action, and it is difficult to have a chance to move to the vicinity of the detection molecule 53 of the working electrode, and interact with the detection molecule. The combination of 53, that is, concentrated mass transfer is a necessary means to improve the sensitivity of detection. As shown in Figure 5D, a small circulating flow rate is given to the solution, so that the movement of virus 51 becomes a directional movement, especially in the vertical direction. Working electrode, and let the flow rate be very small, or flow for a period of time, and stand still for a period of time, giving a chance for stable combination, and also perform signal measurement and processing at the same time.
因此本发明无需上面介绍的生物气溶胶的常用取样方法,必须依赖于捕获颗粒的实验室分析。本发明可以有效达成直接对采样点提供敏感的检测,识别和量化。The present invention therefore does not require the usual sampling methods of bioaerosols described above and must rely on laboratory analysis of captured particles. The present invention can effectively achieve sensitive detection, identification and quantification directly to the sampling point.
就感测芯片24量测的实施例,可以选用各种常见的量测方法,例如光学(Optical)包含表面等离振子法(surface plasmon resonance,SPR),比色(colorimetric)法,化学发光法(chemiluminescence,CL),荧光法(fluorescence),表面增强拉曼散射法(surface-enhanced Raman scattering,SERS)和干涉法(interferometry)。For the embodiment of the measurement of the sensing chip 24, various common measurement methods can be selected, such as optical (Optical) including surface plasmon resonance (SPR), colorimetric (colorimetric) method, chemiluminescence method (chemiluminescence, CL), fluorescence (fluorescence), surface-enhanced Raman scattering (surface-enhanced Raman scattering, SERS) and interference (interferometry).
感测芯片量测24的实施例也可采用电学(Electrical)法,当目标物与抗体或适体之间的结合引起或改变电信号时,即可侦测目标物的浓度。根据其检测机理可分为电学法,或压电换能器法,或场效晶体管(FET)法。也可使用纳米孔(nanopore),(参考Niedzwiecki,D.J.,Iyer,R.,Borer,P.N.,and Movileanu,L.(2013).Sampling a biomarker of the human immunodeficiency virus across a synthetic nanopore.ACS Nano 7,3341–3350.),其中电学法所述讯号处理单元主要选自电化学感测电路、安培法、方波伏安法(square wave voltammetry,SWV)、差式脉波伏安法(Differential Pulse Voltammetry,DPV)、计时安培法(chronoamperometry)、间歇脉冲安培法(intermittent pulse amperometry,IPA)、快速扫描循环伏安法(fast-scan cyclic voltammogram,FSCV)、电化学阻抗频谱法(Electrochemical Impedance Spectrum,EIS)或其组合。The embodiment of the sensing chip measurement 24 can also use an electrical method. When the binding between the target and the antibody or aptamer causes or changes the electrical signal, the concentration of the target can be detected. According to its detection mechanism, it can be divided into electrical method, piezoelectric transducer method, or field effect transistor (FET) method. Nanopores can also be used, (see Niedzwiecki, D.J., Iyer, R., Borer, P.N., and Movileanu, L. (2013). Sampling a biomarker of the human immunodeficiency virus across a synthetic nanopore. ACS Nano 7, 3341–3350.), wherein the signal processing unit described in the electrical method is mainly selected from electrochemical sensing circuits, amperometric methods, square wave voltammetry (SWV), differential pulse voltammetry (Differential Pulse Voltammetry) , DPV), chronoamperometry (chronoamperometry), intermittent pulse amperometry (intermittent pulse amperometry, IPA), fast-scan cyclic voltammogram (fast-scan cyclic voltammogram, FSCV), electrochemical impedance spectroscopy (Electrochemical Impedance Spectrum, EIS) ) or a combination thereof.
对于上述类型的感测芯片14,某些实施例可以在感测芯片14上方修饰添加使用纳米材料来支持用于捕获目标物的适体或抗体,并且有些纳米材料还参与信号转换,这样通常可增加传感器的灵敏度。这些纳米材料包含纳米磁珠、纳米金、碳管、石墨烯、ZnO等。这些纳米材料进一步结合硫氨酸(thionine,THI)或普鲁士蓝(Prussian Blue,PB),以增强电 化学检测时的氧化还原反应。For the above-mentioned type of sensing chip 14, some embodiments may modify the sensing chip 14 by adding nanomaterials to support aptamers or antibodies for capturing the target, and some nanomaterials are also involved in signal conversion. Increase the sensitivity of the sensor. These nanomaterials include nanomagnetic beads, nanogold, carbon tubes, graphene, ZnO, etc. These nanomaterials were further combined with thionine (THI) or Prussian Blue (PB) to enhance the redox reaction during electrochemical detection.
本发明特别以使用电化阻抗频谱法(Electrochemical Impedance Spectrum,EIS)实施例来说明,该感测芯片14可由金工作电极,溶液PBS添加赤血盐/黄血盐5mM或其他氧化还原离子,例如六氨合钌(II)/(III)(Hexaammineruthenium(II)/(III)),可以延长期使用与保存时间。采用法拉第电流量测方法,以确保其灵敏度可达到0.1pg/mL等级甚至更好的检测限(LOD)。The present invention is particularly illustrated by using an example of Electrochemical Impedance Spectrum (EIS), the sensing chip 14 can be made of a gold working electrode, the solution PBS is added with red blood salt/yellow blood salt 5mM or other redox ions, such as six Ammonium ruthenium(II)/(III) (Hexaammineruthenium(II)/(III)), can prolong the use and storage time. The Faraday current measurement method is used to ensure that its sensitivity can reach the limit of detection (LOD) of the order of 0.1pg/mL or better.
在某些实施例中也可以使用电化阻抗频谱法(EIS),但使用非法拉第的量测方法,也就是让金电极成为梳状交叉结构,正负电极之间的间距为10-50微米。则病菌与病毒的浓度与阻抗变化成一正比。In some embodiments, electrochemical impedance spectroscopy (EIS) can also be used, but a Faraday measurement method is used, that is, the gold electrodes are formed into a comb-like interdigitated structure, and the spacing between the positive and negative electrodes is 10-50 microns. Then the concentration of bacteria and viruses is proportional to the impedance change.
在某些实施例中,先将适体/酵素结合体71涂布于可更换的感测芯片14的电极以外的区域上。要使用时,将该感测芯片14插入本发明装置的PBS中,使适体/酵素结合体71溶解于PBS中,让该结合体71中的第一适体711能与捕捉进PBS中的病菌或病毒72进行专一性接合,同时这些带有结合体71的病菌或病毒72也会因为循环水流靠近感测芯片14,并因此与固定于芯片上工作电极WE的第二适体73结合,而且之后也可能有更多的适体/酵素结合体71会与在芯片工作电极WE上被第二适体73捕捉病菌或病毒成为三明治的结合。其中的适体/酵素结合体71中的酵素712选自氧化还原酶例如辣根过氧化物酶(Horseradish peroxidase,HRP),通过耦合程序组成适体/酵素(aptamer-biotin-streptavidin-HRP)。In some embodiments, the aptamer/enzyme combination 71 is first coated on the area other than the electrodes of the replaceable sensor chip 14 . To use, insert the sensing chip 14 into the PBS of the device of the present invention, so that the aptamer/enzyme conjugate 71 is dissolved in PBS, so that the first aptamer 711 in the conjugate 71 can interact with the aptamer captured in the PBS. The germs or viruses 72 are specifically bound, and at the same time, these germs or viruses 72 with the binding bodies 71 will also be close to the sensing chip 14 due to the circulating water flow, and thus bind to the second aptamer 73 immobilized on the working electrode WE on the chip. , and there may be more aptamer/enzyme conjugates 71 that will combine with the bacteria or viruses captured by the second aptamer 73 on the chip working electrode WE to form a sandwich. The enzyme 712 in the aptamer/enzyme combination 71 is selected from oxidoreductases such as horseradish peroxidase (Horseradish peroxidase, HRP), and the aptamer/enzyme (aptamer-biotin-streptavidin-HRP) is formed through a coupling procedure.
在该检测平台基于场效应酶检测(Field Effect Enzymatic Detection,FEED)技术。该方法采用免疫测定平台,无需培养富集即可直接检测样品中的细菌或病毒。图7是本发明实施例的场效应酶检测平台的示意图。门控电压74在溶液-酶-电极界面感应电场,以减小电子的隧道势垒。因此,电极和HRP之间的隧道电流即信号电流被门控电压74放大。平台由于信号放大而提供的病毒与细菌超灵敏定量检测功能,可直接检测极低浓度样品中的生物气溶胶的病毒或细菌,而无需进行样品处理。The detection platform is based on Field Effect Enzymatic Detection (FEED) technology. The method uses an immunoassay platform to directly detect bacteria or viruses in samples without culture enrichment. FIG. 7 is a schematic diagram of a field-effect enzyme detection platform according to an embodiment of the present invention. The gate voltage 74 induces an electric field at the solution-enzyme-electrode interface to reduce the tunneling barrier for electrons. Therefore, the tunneling current between the electrodes and the HRP, the signal current, is amplified by the gate voltage 74 . The platform provides ultra-sensitive quantitative detection of viruses and bacteria due to signal amplification, which can directly detect viruses or bacteria in bioaerosols in extremely low-concentration samples without sample processing.
于原来的三电极(WE-CE-RE)感测芯片14上,工作电极WE先固定第二适体73。Gating电极GE 75的制作,例如使用厚铜箔胶带喷上绝缘漆,或是漆包铜线等,做成U型,图8所示,一端与金手指焊接,另一端自由。这个方法对于侦测病菌与病毒,都很适合。该检测基于Horseradish peroxidase(HRP)还原峰电流的放大,透过绘制基线来测量峰高,并由cyclic voltammogram(CV)判断。On the original three-electrode (WE-CE-RE) sensing chip 14 , the second aptamer 73 is first fixed to the working electrode WE. For the production of Gating electrode GE 75, for example, use thick copper foil tape to spray insulating paint, or enameled copper wire, etc., to make a U shape, as shown in Figure 8, one end is welded with gold fingers, and the other end is free. This method is suitable for detecting bacteria and viruses. The assay is based on the amplification of the horseradish peroxidase (HRP) reduction peak current, and the peak height is measured by drawing a baseline and judged by the cyclic voltammogram (CV).
就飞沫传染的病毒与病菌的结构而言,其相关组成的蛋白质,都可能出现于受病毒或病菌感染的宿主身上,并且可能会出现于宿主的飞沫中,因此使用多合一的传感器,可以增加感测的灵敏度与精准度。例如针对冠状病毒,如SARS,SARS-COV-2,MERS等,其病毒结构的蛋白质包含穗状糖蛋白(Spike glycoprotein),包膜蛋白(Envelope protein), 跨膜糖蛋白(TransMembrane glycoprotein),核衣壳蛋白(Nucleocapsid protein)等,因此在多合一的传感器芯片的工作电极上可布植固定的探测分子,并选自针对穗状糖蛋白(Spike glycoprotein),包膜蛋白(Envelope protein),跨膜糖蛋白(TransMembrane glycoprotein),核衣壳蛋白(Nucleocapsid protein),的抗体或适体,或是针对ssRNA的核苷酸分子。其中,例如针对穗状糖蛋白(Spike glycoprotein)的抗体,可以是IgA,IgM,IgG其中一者,或IgG,IgM两者或IgA,IgG两者,或是IgA,IgM,IgG三者。As far as the structure of droplet-infected viruses and bacteria is concerned, the related proteins may appear in the host infected by the virus or bacteria, and may appear in the droplets of the host, so an all-in-one sensor is used. , which can increase the sensitivity and accuracy of the sensing. For example, for coronaviruses, such as SARS, SARS-COV-2, MERS, etc., the proteins of its viral structure include Spike glycoprotein, Envelope protein, TransMembrane glycoprotein, nuclear Capsid protein (Nucleocapsid protein), etc. Therefore, fixed detection molecules can be implanted on the working electrode of the all-in-one sensor chip, and selected from Spike glycoprotein (Spike glycoprotein), Envelope protein (Envelope protein), Transmembrane glycoprotein (TransMembrane glycoprotein), nucleocapsid protein (Nucleocapsid protein), antibodies or aptamers, or nucleotide molecules against ssRNA. Among them, for example, the antibody against Spike glycoprotein can be one of IgA, IgM, and IgG, or both of IgG and IgM, or both of IgA and IgG, or three of IgA, IgM, and IgG.
本发明的装置可以推算空气目标生物气溶胶的浓度CtThe device of the present invention can estimate the concentration Ct of the air target bioaerosol
Ct=(M/V)/ECt=(M/V)/E
其中,E=CR1 X CR2 X CR3生物气溶胶感测系统捕捉与收集效率,Among them, E=CR1 X CR2 X CR3 bioaerosol sensing system capture and collection efficiency,
捕捉率Capture Ratio的计算包含:1.空气杂质过滤捕捉率CR1;2.冲击式油膜33与翻转油膜33进入PBS的捕捉率CR2;3.循环流动或PWM扰动,捕捉率CR3;目标物收集质量M=CxVpbs(ng);PBS容积Vpbs(mL);感测芯片14感测到目标物的浓度C(ng/mL);收集气体容积V=QxT;抽气帮浦流量Q(L/min);抽气时间T(min)。The calculation of capture rate Capture Ratio includes: 1. Air impurity filtration capture rate CR1; 2. Capture rate CR2 of impact oil film 33 and inverted oil film 33 entering PBS; 3. Circulating flow or PWM disturbance, capture rate CR3; target collection quality M=CxVpbs (ng); PBS volume Vpbs (mL); the sensing chip 14 senses the target concentration C (ng/mL); the collected gas volume V=QxT; the pump flow Q (L/min) ; Pumping time T (min).
本发明在侦测到病原体后,更换相关耗材的步骤如下:After the present invention detects pathogens, the steps of replacing relevant consumables are as follows:
去除抽气风扇前的过滤纸;Remove the filter paper in front of the exhaust fan;
去除感测芯片14;remove the sensing chip 14;
去除PBS储槽,PBS/油膜等模块。Remove modules such as PBS reservoir, PBS/oil film, etc.
消毒:将剩余的模块与装备,使用酒精擦拭或喷涂,或使用紫外光,进行照射,以杀死残留的病原体,紫外光的杀病原体功效,参考“Far-UVC light:A new tool to control the spread of airborne-mediated microbial diseases”Scientific RePortS|(2018)8:2752|DOI:10.1038/s41598-018-21058-wDisinfection: Wipe or spray the remaining modules and equipment with alcohol, or use ultraviolet light to irradiate to kill residual pathogens. For the pathogen-killing effect of ultraviolet light, refer to "Far-UVC light: A new tool to control the spread of airborne-mediated microbial diseases” Scientific RePortS|(2018)8:2752|DOI:10.1038/s41598-018-21058-w
更换新的PBS储槽,PBS/油膜等模块,Replace the new PBS storage tank, PBS/oil film and other modules,
更换新的感测芯片14。Replace the sensor chip 14 with a new one.
装上新的过滤纸于抽气风扇前。Install a new filter paper in front of the extraction fan.
实施例1--流感病毒的侦测Example 1 - Detection of Influenza Virus
人类的许多呼吸道病毒来源于动物。例如,现在有八种副粘病毒(paramyxoviruses),四种冠状病毒和四种正粘病毒(orthomxoviruses)引起人类经常性流行,但一度限于其他宿主。在过去的十年中,同一病毒家族的几个成员已经跳过了从动物到人类的物种屏障。幸运的是,这些病毒尚未在人类中建立,因为它们缺乏人与人之间持续传播的能力。然而,多次爆发显示我们对病毒可传播的原因缺乏了解。部分原因是流感病毒人畜共患病和流行病发生频率相对较高,流感研究界已开始调查通过气溶胶或哺乳动物呼吸道飞沫驱动病毒传播的病毒基因和生物学特性。我们总结了最近关于H5,H7和H9亚型人畜共患流感病毒以及H1,H2和H3亚型流感病毒空中传播所需基因和表型特征的发现。Many respiratory viruses in humans originate from animals. For example, there are now eight paramyxoviruses, four coronaviruses, and four orthomxoviruses that cause recurrent human epidemics, but were once limited to other hosts. Over the past decade, several members of the same virus family have jumped the species barrier from animals to humans. Fortunately, these viruses have not yet established in humans because they lack the ability to transmit continuously from person to person. However, multiple outbreaks have shown our lack of understanding of how the virus can spread. In part because of the relatively high zoonotic and epidemic frequency of influenza viruses, the influenza research community has begun to investigate the viral genes and biology that drive viral transmission through aerosols or mammalian respiratory droplets. We summarize recent findings on the genetic and phenotypic characteristics required for airborne transmission of zoonotic influenza viruses of subtypes H5, H7, and H9, and influenza viruses of subtypes H1, H2, and H3.
流感侦测主要是以Hemoglutin抗原为主,所以制造上可使用H1-H16的Aptamer来制作感测芯片14,基本只要每种H型抗原单独制作,或六合一,只要生产三种型式即可涵盖所有流感病毒的种类与变异组合。如图6所示,为二合一感测芯片,包含两个工作电极61,两个反电极63,共享一个参考电极65,设置两种不同H型抗原的适体,例如针对H1,和H3亚型流感病毒;或是三合一感测芯片,设置三种不同H型抗原的适体,例如H1,H2和H3亚型流感病毒;或是H5,H7和H9亚型人畜共患流感病毒。或是在四合一感测芯片H1,H3,H5,H9;或是在六合一感测芯片,设置六种不同H型抗原的适体,例如H1,H2和H3亚型流感病毒、H5,H7和H9亚型人畜共患流感病毒。Influenza detection is mainly based on Hemoglutin antigen, so H1-H16 Aptamer can be used to make sensor chip 14. Basically, as long as each H-type antigen is made separately, or six-in-one, as long as three types are produced, it can be covered All influenza virus species and variant combinations. As shown in FIG. 6, it is a two-in-one sensing chip, including two working electrodes 61, two counter electrodes 63, sharing a reference electrode 65, and setting aptamers for two different H-type antigens, such as for H1, and H3 Subtype influenza virus; or a three-in-one sensor chip with aptamers of three different H-type antigens, such as H1, H2 and H3 subtype influenza viruses; or H5, H7 and H9 subtype zoonotic influenza viruses . Or in the four-in-one sensor chip H1, H3, H5, H9; or in the six-in-one sensor chip, set six different H-type antigen aptamers, such as H1, H2 and H3 subtype influenza virus, H5, Zoonotic influenza viruses of subtypes H7 and H9.
将感测芯片14的工作电极通过在0.5M H 2SO 4中以0.1V/s的速度在-0.2和+1.2V之间循环电势对金工作电极进行电化学处理,直到获得可再现的循环伏安图。随后在100μL磷酸盐缓冲液(PBS:10mM磷酸盐缓冲液,5mM MgCl 2)中加入0.5μM具有低聚乙二醇间隔基的硫醇化适体探针(HS-(CH 2CH 2O)18-GGACCAGTTGTCTTTCGGTCTCTACCCCAGCCCGT),pH7.4在95°C下孵育10分钟,然后冷却至室温。然后,将HS-A20S溶液与1μL tris-(2-carboxyethyl)phosphine hydrochloride(TCEP)储备溶液(100mM)混合。将混合物保持1小时以还原二硫醇键。然后将干净的金电极浸入上述溶液中,并在室温下保持12小时。电极用PBS漂洗,浸入MCH水溶液(1mM)中4h。使用前,将功能化电极用PBS彻底冲洗3次。 The working electrode of the sensing chip 14 was electrochemically treated by cycling the gold working electrode between -0.2 and +1.2 V at 0.1 V/s in 0.5 M H 2 SO 4 until reproducible cyclic volts were obtained. Antu. Then 0.5 μM of the thiolated aptamer probe with an oligoethylene glycol spacer (HS-(CH 2 CH 2 O) 18 was added to 100 μL of phosphate buffered saline (PBS: 10 mM phosphate buffered saline, 5 mM MgCl 2 ) 18 -GGACCAGTTGTCTTTCGGTCTCTACCCCAGCCCGT), pH 7.4, incubated at 95°C for 10 minutes, then cooled to room temperature. Then, the HS-A20S solution was mixed with 1 μL of tris-(2-carboxyethyl)phosphine hydrochloride (TCEP) stock solution (100 mM). The mixture was kept for 1 hour to reduce the dithiol bonds. The clean gold electrodes were then immersed in the above solution and kept at room temperature for 12 hours. The electrodes were rinsed with PBS and immersed in aqueous MCH (1 mM) for 4 h. The functionalized electrodes were rinsed thoroughly with PBS 3 times before use.
所有电化学测量均在室温下在EIS讯号读取电路上进行,使用由适体修饰的金电极作为工作电极(WE),Ag/AgCl参考电极(RE),以及金电极(CE)作为对电极。将适体功能化的电极与病毒样品(H1N1,B和H7N9)在含有1M NaCl/5mM K 3Fe(CN) 6/5mM K 4Fe(CN) 6的PB溶液中于室温下孵育30分钟后,然后以0.03Hz至200kHz的频率范围内的10mV振幅收集EIS。 All electrochemical measurements were performed at room temperature on an EIS signal readout circuit using an aptamer-modified gold electrode as the working electrode (WE), the Ag/AgCl reference electrode (RE), and the gold electrode (CE) as the counter electrode . After incubation of the aptamer-functionalized electrodes with virus samples (H1N1, B and H7N9) in PB solution containing 1M NaCl /5mM K3Fe (CN) 6 /5mM K4Fe(CN) 6 for 30 min at room temperature , and then collected EIS with 10 mV amplitude in the frequency range from 0.03 Hz to 200 kHz.
实施例2--新冠病毒SARS-CoV-2免疫传感器Example 2--New coronavirus SARS-CoV-2 immunosensor
SARS-CoV-2的结构;由刺突蛋白组成;它包括两个区域S1和S2,其中S1用于宿主细胞受体结合,S2用于膜融合。刺突蛋白是用抗体和疫苗中和的典型靶标。据报导,SARS-CoV-2可以感染人类呼吸道上皮细胞的速度是以前的冠状病毒株的100-1000倍,并且可以通过与人类ACE2受体相互作用来感染。Structure of SARS-CoV-2; consists of a spike protein; it includes two regions, S1 and S2, where S1 is used for host cell receptor binding and S2 is used for membrane fusion. Spike proteins are typical targets for neutralization with antibodies and vaccines. SARS-CoV-2 has been reported to infect human respiratory epithelial cells 100-1000 times faster than previous coronavirus strains and by interacting with the human ACE2 receptor.
核衣壳蛋白是SARS-CoV-2中含量最丰富的蛋白。N蛋白是一种高度免疫原性的磷蛋白,很少发生变化。SARS-CoV-2的N蛋白通常在诊断分析中用作标记。Nucleocapsid protein is the most abundant protein in SARS-CoV-2. The N protein is a highly immunogenic phosphoprotein that rarely changes. The N protein of SARS-CoV-2 is often used as a marker in diagnostic assays.
尽管IgG抗体可确认持续存在,甚至过去的感染,但IgA抗体却被描述为急性呼吸道感染的早期标志物。在最近的一项研究中(Okba等人,doi:10.1101/2020.03.18.20038059;2020年3月),证实了特异性IgA检测对急性SARS-CoV-2感染的早期诊断具有附加价值。ELISA的良好敏感性和特异性也已被证明。SARS-CoV-2ELISA中使用的抗原(IgA和IgG),即刺突蛋白S1域,对SARS-CoV-2抗体的血清学检测比对保守性较高的N蛋白-或全长S蛋 白更具特异性。While IgG antibodies can confirm persistent, even past infection, IgA antibodies have been described as an early marker of acute respiratory infection. In a recent study (Okba et al., doi: 10.1101/2020.03.18.20038059; March 2020), the added value of specific IgA detection for the early diagnosis of acute SARS-CoV-2 infection was demonstrated. Good sensitivity and specificity of ELISA have also been demonstrated. The antigens (IgA and IgG) used in the SARS-CoV-2 ELISA, the Spike protein S1 domain, are more serologically detectable for SARS-CoV-2 antibodies than for the more conserved N- or full-length S protein. specificity.
通过将金电极(Au)在含有1mM 16MHDA的乙醇溶液中浸泡24小时来形成MHDA的自组装单层(SAM)。SAM形成后,在5mM EDC,15mM NHS和PBS溶液的混合物中于室温下处理Au/MHDA电极20分钟,以活化MHDA的羧酸基团。随后,通过将修饰的电极在含有100μg/mL储备液的0.1M PBS溶液(pH7.4)中于37℃孵育约1小时,将COVID-19的抗体IgG与IgM共价固定在Au/MHA电极上。A self-assembled monolayer (SAM) of MHDA was formed by soaking the gold electrode (Au) in an ethanol solution containing 1 mM 16 MHDA for 24 h. After SAM formation, the Au/MHDA electrodes were treated for 20 min at room temperature in a mixture of 5 mM EDC, 15 mM NHS and PBS solutions to activate the carboxylic acid groups of MHDA. Subsequently, the antibody IgG and IgM of COVID-19 were covalently immobilized on the Au/MHA electrode by incubating the modified electrode in 0.1 M PBS solution (pH 7.4) containing 100 μg/mL stock solution at 37 °C for about 1 h. superior.
所有电化学测量均在室温下在EIS讯号读取电路上进行,使用由适体修饰的金电极作为工作电极(WE),Ag/AgCl参考电极(RE),以及金电极(CE)作为对电极。将COVID-19的抗体IgG与IgM修饰过的工作电极与病毒或其S蛋白或N蛋白在含有1M NaCl/5mM K 3Fe(CN) 6/5mM K 4Fe(CN) 6的PB溶液中于室温下孵育10分钟后,然后以0.03Hz至200kHz的频率范围内的10mV振幅收集EIS。 All electrochemical measurements were performed at room temperature on an EIS signal readout circuit using an aptamer-modified gold electrode as the working electrode (WE), the Ag/AgCl reference electrode (RE), and the gold electrode (CE) as the counter electrode . The COVID-19 antibody IgG and IgM modified working electrode and virus or its S protein or N protein were placed in PB solution containing 1M NaCl/5mM K 3 Fe(CN) 6 /5mM K 4 Fe(CN) 6 After 10 min incubation at room temperature, EIS were then collected at 10 mV amplitude in the frequency range from 0.03 Hz to 200 kHz.
实施例3--新冠病毒SARS-CoV-2适体传感器Example 3--New coronavirus SARS-CoV-2 aptamer sensor
51-nt3发夹结构的CoV2-RBD-1C适体(5’-CAGCACCGACCTTGTGCTTTGGGAGTGCTGGTCCAAGGGCGTTAATGGACA-3’)。这个适体对于RBD的Kd值为5.8±0.8nM。A 51-nt3 hairpin aptamer for CoV2-RBD-1C (5'-CAGCACCGACCTTGTGCTTTGGGAGTGCTGGTCCAAGGGCGTTAATGGACA-3'). The Kd value of this aptamer for RBD was 5.8 ± 0.8 nM.
67-nt发夹结构的CoV2-RBD-4C(5’67-nt hairpin structure of CoV2-RBD-4C (5'
-ATCCAGAGTGACGCAGCATTTCATCGGGTCCAAAAGGGGCTGCTCGGGATTGCGGATATGGACACGT-3’)。这个适体对于RBD的Kd值为19.9±2.6nM。- ATCCAGAGTGACGCAGCATTTCATCGGGTCCAAAAGGGGCTGCTCGGGATTGCGGATATGGACACGT-3'). The Kd value of this aptamer for RBD was 19.9 ± 2.6 nM.
本实施例使用NG-THI-AuNPs纳米复合材料来修饰工作电极,NG-THI-AuNPs纳米复合材料的合成过程如下:将总共2mgNG与2mL超纯水在圆底烧瓶中混合,然后超声处理30分钟以形成稳定的NG溶液。之后,将2mL的THI溶液(2mg/mL)加入上述烧瓶中,然后剧烈搅拌24h。由于苯环之间的π-π堆积相互作用,THI分子将非共价结合到NG表面。通过离心和洗涤数次除去未整合的THI分子,以获得NG-THI纳米复合材料。然后将合成后的纳米复合材料分散在2mL水中。然后将直径约15nm的10mL AuNPs溶液添加至上述分散体中并搅拌过夜以促进AuNPs与NG的氨基完全整合。根据文献制备了AuNPs(Guo and Wang,2007)。最后,在洗涤和离心后,获得NG-THI-AuNPs纳米复合材料,并在4℃下储存以备进一步使用。This example uses NG-THI-AuNPs nanocomposite to modify the working electrode. The synthesis process of NG-THI-AuNPs nanocomposite is as follows: a total of 2 mg of NG is mixed with 2 mL of ultrapure water in a round bottom flask, and then sonicated for 30 minutes to form a stable NG solution. After that, 2 mL of THI solution (2 mg/mL) was added to the above flask, followed by vigorous stirring for 24 h. THI molecules will be non-covalently bound to the NG surface due to the π-π stacking interaction between the benzene rings. Unintegrated THI molecules were removed by centrifugation and washing several times to obtain NG-THI nanocomposites. The synthesized nanocomposites were then dispersed in 2 mL of water. Then 10 mL of AuNPs solution with a diameter of about 15 nm was added to the above dispersion and stirred overnight to promote the complete integration of AuNPs with the amino groups of NG. AuNPs were prepared according to the literature (Guo and Wang, 2007). Finally, after washing and centrifugation, NG-THI-AuNPs nanocomposites were obtained and stored at 4 °C for further use.
在SARS-CoV-2病毒适体感测芯片14的制备过程中,将10μLNG-THI-AuNPs纳米复合材料涂覆在相应的工作电极。将修改后的设备在50℃的烤箱中放置半小时。然后将10μL新冠病毒适体滴到NG-THI-AuNPs修饰电极的表面上,然后用1mLTE缓冲液(10mM Tris-HCl,1mM EDTA,pH7.4)中除去未结合的适体。新冠病毒适体的浓度优化为28μg/mL。由于适体已经在5'端被巯基修饰,这有助于它们通过Au-S键与AuNPs结合。接下来,使用10μL 1mM MCH溶液封闭任何非特异性结合位点。在室温下孵育1小时后,用1mL TE缓冲液将修饰的 适体感测芯片洗涤3次。制备的好的适体感测芯片,使用时,可装入本发明的生物气溶胶检测装置,并连接读取电路模块,使用DPV量测PB溶液中SARS-CoV-2病毒的浓度,并反算空气中SARS-CoV-2病毒的浓度。During the preparation of the SARS-CoV-2 virus aptamer sensing chip 14, 10 μLNG-THI-AuNPs nanocomposites were coated on the corresponding working electrodes. Place the modified device in a 50°C oven for half an hour. Then, 10 μL of 2019-nCoV aptamer was dropped onto the surface of the NG-THI-AuNPs modified electrode, and then the unbound aptamer was removed with 1 mL of LTE buffer (10 mM Tris-HCl, 1 mM EDTA, pH 7.4). The concentration of SARS-CoV-2 aptamer was optimized to 28 μg/mL. Since the aptamers have been modified with sulfhydryl groups at the 5' end, this facilitates their binding to AuNPs via Au-S bonds. Next, block any non-specific binding sites with 10 μL of 1 mM MCH solution. After 1 hour incubation at room temperature, the modified aptamer sensor chip was washed 3 times with 1 mL of TE buffer. The prepared aptamer sensing chip can be loaded into the bioaerosol detection device of the present invention when used, and connected to the reading circuit module, using DPV to measure the concentration of SARS-CoV-2 virus in the PB solution, and inversely calculate The concentration of SARS-CoV-2 virus in the air.
实施例4--SARS病毒传感器。Example 4 - SARS virus sensor.
对SARS病毒的核衣壳蛋白(nucleocapsid protein)具有专一性的适体可参考韩国专利KR20120139512,或是Cho,S.J.,Woo,H.M.,Kim,K.S.,Oh,J.W.,and Jeong,Y.J.(2011).Novel system for detecting SARS coronavirus nucleocapsid protein using an ssDNA aptamer.J.Biosci.Bioeng.112,535–540.所提出的两种DNA适体,第一种For aptamers specific for the nucleocapsid protein of SARS virus, please refer to Korean Patent KR20120139512, or Cho, S.J., Woo, H.M., Kim, K.S., Oh, J.W., and Jeong, Y.J. (2011) .Novel system for detecting SARS coronavirus nucleocapsid protein using an ssDNA aptamer.J.Biosci.Bioeng.112,535–540. Two proposed DNA aptamers, the first
GCAATGGTACGGTACTTCCGGATGCGGAAACTGGCTAATTGGTGAGGCTGGGGCGGTCGTGCAGCAAAAGTGCACGCTACTTTGCTAA,GCAATGGTACGGTACTTCCGGATGCGGAAACTGGCTAATTGGTGAGGCTGGGGCGGTCGTGCAGCAAAAGTGCACGCTACTTTGCTAA,
第二种the second
GCAATGGTACGGTACTTCCCCGTAGATCGAGGGAGCGCATTAAGGTATACGCCCTTCCCATCTTCAAAAGTGCACGCTACTTTGCTAAGCAATGGTACGGTACTTCCCCGTAGATCGAGGGAGCGCATTAAGGTATACGCCCTTCCCATCTTCAAAAGTGCACGCTACTTTGCTAA
为了让该适体能容易固定于工作电极的金表面,因此5'末端用6位碳连接体上的硫醇修饰,In order to allow the aptamer to be easily immobilized on the gold surface of the working electrode, the 5' end was modified with a thiol on the 6-position carbon linker,
5'-HS–(CH 2) 6-GCAATGGTACGGTACTTCCGGATGCGGAAACTGGCTAATTGGTGAGGCTGGGGCGGTCGTGCAGCAAAAGTGCACGCTACTTTGCTAA-(CH 2) 2-3’ 5'-HS–(CH 2 ) 6 -GCAATGGTACGGTACTTCCGGATGCGGAAACTGGCTAATTGGTGAGGCTGGGGCGGTCGTGCAGCAAAAGTGCACGCTACTTTGCTAA-(CH 2 ) 2 -3'
5'-HS–(CH 2) 6-GCAATGGTACGGTACTTCCCCGTAGATCGAGGGAGCGCATTAAGGTATACGCCCTTCCCATCTTCAAAAGTGCACGCTACTTTGCTAA-(CH 2) 2-3’ 5'-HS–(CH 2 ) 6 -GCAATGGTACGGTACTTCCCCGTAGATCGAGGGAGCGCATTAAGGTATACGCCCTTCCCATCTTCAAAAGTGCACGCTACTTTGCTAA-(CH 2 ) 2 -3'
感测芯片的制备与EIS量测可参考实施例1。The fabrication of the sensing chip and the EIS measurement can refer to Example 1.
实施例5--诺罗病毒(Norovirus)的侦测Example 5 - Detection of Norovirus
诺罗病毒(Norovirus),or或杯状病毒(Calicivirus)是病毒性胃肠炎的最常见原因,也称为冬季呕吐病。每年的爆发使数百名工作人员和成千上万的病人数日无法工作,并导致全世界发达国家医院的整个病房关闭。Norovirus, or Calicivirus, is the most common cause of viral gastroenteritis, also known as winter vomiting sickness. The annual outbreak keeps hundreds of staff and tens of thousands of patients out of work for days and shuts down entire wards in hospitals in developed countries around the world.
诺罗病毒(Norovirus),衣壳蛋白质(Capsid protein)如下所示Norovirus (Norovirus), capsid protein (Capsid protein) is shown below
5'-HS–(CH 2) 6-GTCTGTAGTAGGGAGGATGGTCCGGGGCCCCGAGACGACGTTATCAGGC-3′ 5'-HS–(CH 2 ) 6 -GTCTGTAGTAGGGAGGATGGTCCGGGGCCCCGAGACGACGTTATCAGGC-3'
本实施例使用PB-PEDOT-AuNPs纳米复合材料来修饰工作电极,PB-PEDOT-AuNPs纳米复合材料的合成程序如下,PB-PEDOT纳米复合材料是通过在Fe3+离子存在下EDOT的氧化聚合而合成的。PB-PEDOT纳米复合材料具有核壳结构,可以显著提高PB的稳定性和导电性。简要地说,首先将50μL EDOT溶解在5mL乙醇溶液中,然后转移到25mL 0.1M HCl中以形成稳定溶液。同时,将13.2mg K 3[Fe(CN)6]和10.8mg FeCl 3·6H 2O添加到10mL的0.1M HCl 溶液中,然后超声处理30分钟。在剧烈搅拌下将获得的两种溶液混合在一起。随着反应的进行,混合物的颜色逐渐变成深蓝色,表明形成了PB-PEDOT纳米复合材料。离心并洗涤后,将混合物在烘箱中干燥。最终,将10mL AuNPs溶液添加到2mL PB-PEDOT中悬浮液(1mg/mL)搅拌过夜,形成PB-PEDOT-AuNPs纳米复合材料。 This example uses PB-PEDOT-AuNPs nanocomposite to modify the working electrode. The synthesis procedure of PB-PEDOT-AuNPs nanocomposite is as follows. PB-PEDOT nanocomposite is synthesized by oxidative polymerization of EDOT in the presence of Fe3+ ions . The PB-PEDOT nanocomposite has a core-shell structure, which can significantly improve the stability and conductivity of PB. Briefly, 50 μL of EDOT was first dissolved in 5 mL of ethanolic solution and then transferred to 25 mL of 0.1 M HCl to form a stable solution. Meanwhile, 13.2 mg of K 3 [Fe(CN)6] and 10.8 mg of FeCl 3 ·6H 2 O were added to 10 mL of 0.1 M HCl solution, followed by sonication for 30 min. The two solutions obtained were mixed together with vigorous stirring. As the reaction progressed, the color of the mixture gradually changed to dark blue, indicating the formation of PB-PEDOT nanocomposites. After centrifugation and washing, the mixture was dried in an oven. Finally, 10 mL of AuNPs solution was added to 2 mL of PB-PEDOT suspension (1 mg/mL) and stirred overnight to form PB-PEDOT-AuNPs nanocomposites.
在复合适体感测芯片的制备过程中,将10μLPB-PEDOT-AuNPs纳米复合材料涂覆在相应的工作电极。将修改后的设备在50℃的烤箱中放置半小时。然后将另外10μL诺罗病毒(Norovirus),衣壳蛋白质适体引入PB-PEDOT-AuNPs修饰电极上,然后用1mL TE缓冲液(10mM Tris-HCl,1mM EDTA,pH7.4)中除去未结合的适体。诺罗病毒衣壳蛋白质适体的浓度优化为47μg/mL。由于适体已经在5'端被巯基修饰,这有助于它们通过Au-S键与AuNPs结合。接下来,使用10μL 1mM MCH溶液封闭任何非特异性结合位点。在室温下孵育1小时后,用1mL TE缓冲液将修饰的适体感测芯片洗涤3次。制备的好的适体感测芯片,使用时,可装入本发明的生物气溶胶检测装置,并连接读取电路模块,使用DPV量测PB溶液中SARS-CoV-2病毒的浓度,并反算空气中SARS-CoV-2病毒的浓度。During the fabrication of the composite aptamer sensing chip, 10 μ LPB-PEDOT-AuNPs nanocomposites were coated on the corresponding working electrodes. Place the modified device in a 50°C oven for half an hour. Then another 10 μL of Norovirus (Norovirus), capsid protein aptamer was introduced on the PB-PEDOT-AuNPs modified electrode, followed by 1 mL of TE buffer (10 mM Tris-HCl, 1 mM EDTA, pH 7.4) to remove unbound aptamer. The concentration of norovirus capsid protein aptamer was optimized to 47 μg/mL. Since the aptamers have been modified with sulfhydryl groups at the 5' end, this facilitates their binding to AuNPs via Au-S bonds. Next, block any non-specific binding sites with 10 μL of 1 mM MCH solution. After 1 hour incubation at room temperature, the modified aptamer sensor chips were washed 3 times with 1 mL of TE buffer. The prepared aptamer sensing chip can be loaded into the bioaerosol detection device of the present invention when used, and connected to the reading circuit module, using DPV to measure the concentration of SARS-CoV-2 virus in the PB solution, and inversely calculate The concentration of SARS-CoV-2 virus in the air.
对于飞机上或是任何密闭空间,如何确保通风系统可以快速将病毒或是病菌带走,确实需要有病毒捉器来进行感测反馈。然则空气中,是否有核衣壳蛋白或是病毒本身,就需要来侦测,至少可以确定,核衣壳蛋白没有传染性。但是可帮助确定空气中是否有被病毒感染,引申来说,其实所有具有传染性的病原体,除了侦测病原体本身的数量,病原体各部位的蛋白质都可能在宿主的体内产生于血液中,鼻腔,咽喉,肺部等等。For aircraft or any confined space, how to ensure that the ventilation system can quickly take away viruses or germs, it is indeed necessary to have a virus catcher for sensing feedback. However, whether there is nucleocapsid protein or the virus itself in the air needs to be detected. At least it can be determined that the nucleocapsid protein is not infectious. But it can help determine whether the air is infected by a virus. By extension, in fact, all infectious pathogens, in addition to detecting the number of pathogens themselves, proteins in various parts of the pathogen may be produced in the host's body in the blood, nasal cavity, throat, lungs, etc.
本发明实施例还提供一种生物气溶胶检测的方法,使用上述生物气溶胶检测装置,包括以下步骤:An embodiment of the present invention also provides a method for detecting biological aerosols, using the above-mentioned biological aerosol detecting device, including the following steps:
步骤一、过滤,将通过的待测空气去除非目标生物气溶胶; Step 1, filter, remove the non-target biological aerosol from the air to be tested;
步骤二、抽气,将环境空气利用进气风扇吸入装置;Step 2, air extraction, and the ambient air is sucked into the device by an air intake fan;
步骤三、捕捉收集,将生物气溶胶冲击至装置内油膜/生物缓冲液,让生物气溶胶附着油膜,或是穿越油膜,直接进入生物缓冲液中;Step 3, capturing and collecting, impacting the bioaerosol into the oil film/biological buffer in the device, so that the bioaerosol adheres to the oil film, or passes through the oil film and directly enters the biological buffer;
步骤四、生物气溶胶转水溶胶,利用检测装置的渐缩气道产生冲击力,或是第一泵浦吹开油膜翻转油膜上方捕捉的气溶胶至生物缓冲液中,变成水溶胶;Step 4: The biological aerosol is converted into a hydrosol, and the tapered airway of the detection device is used to generate an impact force, or the first pump blows the aerosol captured above the oil film and flips the oil film into the biological buffer to become a hydrosol;
步骤五、浓缩质传,利用循环流道的设计,将生物缓冲液内的水溶胶全数流动到感测芯片与芯片上的探测分子捕捉结合;Step 5: Concentrating mass transfer, using the design of the circulating flow channel, all the hydrosols in the biological buffer flow to the sensing chip and the detection molecules on the chip are captured and combined;
步骤六、检测,利用感测芯片上的探测分子捕捉结合,产生的讯号改变,进行目标生物气溶胶的浓度侦测。Step 6: Detecting, using the detection molecules on the sensing chip to capture and combine, and the resulting signal changes to detect the concentration of the target biological aerosol.
在本发明的描述中,需要理解的是,术语“中心”、“纵向”、“横向”、“长度”、“宽度”、“厚度”、“上”、“下”、“前”、“后”、“左”、“右”、“竖直”、“水平”、“顶”、“底”“内”、“外”、“顺时针”、“逆时针”等指示的方位或位 置关系为基于附图所示的方位或位置关系,仅是为了便于描述本发明和简化描述,而不是指示或暗示所指的装置或元件必须具有特定的方位、以特定的方位构造和操作,因此不能理解为对本发明的限制。In the description of the present invention, it should be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", " Rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inside", "outside", "clockwise", "counterclockwise", etc. The relationship is based on the orientation or positional relationship shown in the drawings, which is only for the convenience of describing the present invention and simplifying the description, rather than indicating or implying that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore It should not be construed as a limitation of the present invention.
此外,术语“第一”、“第二”仅用于描述目的,而不能理解为指示或暗示相对重要性或者隐含指明所指示的技术特征的数量。由此,限定有“第一”、“第二”的特征可以明示或者隐含地包括一个或者更多个该特征。在本发明的描述中,“多个”的含义是两个或两个以上,除非另有明确具体的限定。In addition, the terms "first" and "second" are only used for descriptive purposes, and should not be construed as indicating or implying relative importance or implying the number of indicated technical features. Thus, a feature defined as "first" or "second" may expressly or implicitly include one or more of that feature. In the description of the present invention, "plurality" means two or more, unless otherwise expressly and specifically defined.
在本发明中,除非另有明确的规定和限定,术语“安装”、“相连”、“连接”、“固定”等术语应做广义理解,例如,可以是固定连接,也可以是可拆卸连接,或成一体;可以是机械连接,也可以是电连接;可以是直接相连,也可以通过中间媒介间接相连,可以是两个元件内部的连通或两个元件的相互作用关系。对于本领域的普通技术人员而言,可以根据具体情况理解上述术语在本发明中的具体含义。In the present invention, unless otherwise expressly specified and limited, the terms "installed", "connected", "connected", "fixed" and other terms should be understood in a broad sense, for example, it may be a fixed connection or a detachable connection , or integrated; it can be a mechanical connection or an electrical connection; it can be a direct connection or an indirect connection through an intermediate medium, and it can be the internal connection of the two elements or the interaction relationship between the two elements. For those of ordinary skill in the art, the specific meanings of the above terms in the present invention can be understood according to specific situations.
在本发明中,除非另有明确的规定和限定,第一特征在第二特征之“上”或之“下”可以包括第一和第二特征直接接触,也可以包括第一和第二特征不是直接接触而是通过它们之间的另外的特征接触。而且,第一特征在第二特征“之上”、“上方”和“上面”包括第一特征在第二特征正上方和斜上方,或仅仅表示第一特征水平高度高于第二特征。第一特征在第二特征“之下”、“下方”和“下面”包括第一特征在第二特征正下方和斜下方,或仅仅表示第一特征水平高度小于第二特征。In the present invention, unless otherwise expressly specified and limited, a first feature "on" or "under" a second feature may include the first and second features in direct contact, or may include the first and second features Not directly but through additional features between them. Also, the first feature being "above", "over" and "above" the second feature includes the first feature being directly above and obliquely above the second feature, or simply means that the first feature is level higher than the second feature. The first feature is "below", "below" and "below" the second feature includes the first feature being directly below and diagonally below the second feature, or simply means that the first feature has a lower level than the second feature.
在本说明书的描述中,参考术语“一个实施例”、“一些实施例”、“示例”、“具体示例”、或“一些示例”等的描述意指结合该实施例或示例描述的具体特征、结构、材料或者特点包含于本发明的至少一个实施例或示例中。在本说明书中,对上述术语的示意性表述不应理解为必须针对的是相同的实施例或示例。而且,描述的具体特征、结构、材料或者特点可以在任何的一个或多个实施例或示例中以合适的方式结合。此外,本领域的技术人员可以将本说明书中描述的不同实施例或示例进行接合和组合。In the description of this specification, description with reference to the terms "one embodiment," "some embodiments," "example," "specific example," or "some examples", etc., mean specific features described in connection with the embodiment or example , structure, material or feature is included in at least one embodiment or example of the present invention. In this specification, schematic representations of the above terms should not be construed as necessarily referring to the same embodiment or example. Furthermore, the particular features, structures, materials or characteristics described may be combined in any suitable manner in any one or more embodiments or examples. Furthermore, those skilled in the art may combine and combine the different embodiments or examples described in this specification.
尽管上面已经示出和描述了本发明的实施例,可以理解的是,上述实施例是示例性的,不能理解为对本发明的限制,本领域的普通技术人员在本发明的范围内可以对上述实施例进行变化、修改、替换和变型。Although the embodiments of the present invention have been shown and described above, it should be understood that the above-mentioned embodiments are exemplary and should not be construed as limiting the present invention. Embodiments are subject to variations, modifications, substitutions and variations.

Claims (10)

  1. 一种生物气溶胶检测装置,其特征在于,包括:A biological aerosol detection device, characterized in that, comprising:
    收集模块,收集模块包括抽气风扇、弧形渐缩气道、第一泵浦、油水容器、第二泵浦;油水容器内设置有油层及生物缓冲液;抽气风扇进气口设置过滤单元,以将吸入空气初步过滤,并经由该弧形渐缩气道产生冲击力将空气中的生物气溶胶收集到油水容器的油层上方,让生物气溶胶吸附于油层表面,然后定时透过第一泵浦将压力风打在油层表面上,使油层翻转,在翻转过程,待测生物气溶胶翻转至油层下,进入生物缓冲液中;Collection module, the collection module includes a suction fan, an arc-shaped tapered air passage, a first pump, an oil-water container, and a second pump; the oil-water container is provided with an oil layer and a biological buffer; the air inlet of the suction fan is provided with a filter unit , to preliminarily filter the inhaled air, and generate impact force through the arc-shaped tapered airway to collect the bio-aerosol in the air above the oil layer of the oil-water container, so that the bio-aerosol is adsorbed on the surface of the oil layer, and then periodically passes through the first The pump hits the pressure air on the surface of the oil layer to turn the oil layer. During the inversion process, the bioaerosol to be tested is turned under the oil layer and enters the biological buffer;
    检测模块,检测模块包括感测芯片单元、讯号处理单元、微控制器单元,各单元电性相连;感测芯片单元上固着至少一探测分子,以检测进入生物缓冲液中特定的生物气溶胶;a detection module, the detection module includes a sensing chip unit, a signal processing unit, and a microcontroller unit, and each unit is electrically connected; at least one detection molecule is fixed on the sensing chip unit to detect a specific biological aerosol entering the biological buffer;
    电源,电源供应收集模块与检测模块所需电力;Power supply, the power supply the power required by the collection module and the detection module;
    其中进入生物缓冲液中的待测生物气溶胶,经由循环的流道设计,配合第二泵浦的驱动,让油层下的生物缓冲液及待测生物气溶胶都会循环流经感测芯片单元,使待测生物气溶胶有效接触探测分子,达成捕捉与检测。The bioaerosol to be tested entering the biological buffer solution is designed with a circulating flow channel and driven by the second pump, so that the biological buffer solution and the bioaerosol to be tested under the oil layer will circulate through the sensing chip unit. The bioaerosol to be tested is effectively contacted with the detection molecules to achieve capture and detection.
  2. 如权利要求1所述的生物气溶胶检测装置,其特征在于:生物气溶胶包括病毒、病菌、真菌、花粉至少其中之一。The bioaerosol detection device according to claim 1, wherein the bioaerosol comprises at least one of viruses, germs, fungi, and pollen.
  3. 如权利要求1所述的生物气溶胶检测装置,其特征在于:检测模块包括无线通讯模块或显示单元。The biological aerosol detection device according to claim 1, wherein the detection module comprises a wireless communication module or a display unit.
  4. 如权利要求1所述的生物气溶胶检测装置,其特征在于:生物缓冲液内含氧化还原离子,氧化还原离子选自赤血盐、黄血盐、六氨合钌、酵素。The bioaerosol detection device according to claim 1, wherein the biological buffer contains redox ions, and the redox ions are selected from the group consisting of red blood salt, yellow blood salt, ruthenium hexaammine, and enzymes.
  5. 如权利要求1所述的生物气溶胶检测装置,其特征在于:探测分子选自适体、抗体或醣分子。The bioaerosol detection device according to claim 1, wherein the detection molecules are selected from aptamers, antibodies or sugar molecules.
  6. 如权利要求1所述的生物气溶胶检测装置,其特征在于:感测芯片上添加用于捕获目标物的适体或抗体使用的纳米材料,纳米材料选自纳米磁珠、纳米金、碳管、石墨烯、ZnO,以及这些纳米材料进一步结合硫氨酸或普鲁士蓝。The bioaerosol detection device according to claim 1, characterized in that: nanomaterials used for aptamers or antibodies for capturing the target are added on the sensing chip, and the nanomaterials are selected from nanomagnetic beads, nanogold, and carbon tubes. , graphene, ZnO, and these nanomaterials are further combined with thionine or Prussian blue.
  7. 如权利要求1所述的生物气溶胶检测装置,其特征在于:感测芯片单元的检测方式为光学法,选自表面等离振子法,比色法,化学发光法,荧光法,表面增强拉曼散射法和干涉法。The bioaerosol detection device according to claim 1, wherein the detection method of the sensing chip unit is an optical method, selected from the group consisting of surface plasmon method, colorimetric method, chemiluminescence method, fluorescence method, surface enhanced pull Mann scattering and interferometry.
  8. 如权利要求1所述的生物气溶胶检测装置,其特征在于:感测芯片单元的检测方式为电学法,当目标物与抗体或适体之间的结合引起或改变电信号时,即可侦测目标物的浓度。The bioaerosol detection device of claim 1, wherein the detection method of the sensing chip unit is an electrical method, and when the binding between the target and the antibody or aptamer causes or changes an electrical signal, the detection can be Measure the concentration of the target.
  9. 如权利要求8所述的生物气溶胶检测装置,其特征在于:电学法的讯号处理单元主要选自方波伏安法、差式脉波伏安法、计时安培法、间歇脉冲安培法、快速扫描循环伏安法、电化学阻抗频谱法、场效应酶检测法或其组合。The bioaerosol detection device of claim 8, wherein the electrical signal processing unit is mainly selected from square wave voltammetry, differential pulse wave voltammetry, chronoamperometry, intermittent pulse amperometry, rapid Scanning cyclic voltammetry, electrochemical impedance spectroscopy, field effect enzymatic detection, or a combination thereof.
  10. 一种生物气溶胶检测的方法,使用权利要求1-9中任一项所述的生物气溶胶检测装置, 其特征在于,包括以下步骤:A method for bioaerosol detection, using the bioaerosol detection device according to any one of claims 1-9, characterized in that, comprising the following steps:
    步骤一、过滤,将通过的待测空气去除非目标生物气溶胶;Step 1, filter, remove the non-target biological aerosol from the air to be tested;
    步骤二、抽气,将环境空气利用进气风扇吸入装置;Step 2, air extraction, and the ambient air is sucked into the device by an air intake fan;
    步骤三、捕捉收集,将生物气溶胶冲击至装置内油膜/生物缓冲液,让生物气溶胶附着油膜,或是穿越油膜,直接进入生物缓冲液中;Step 3, capturing and collecting, impacting the bioaerosol into the oil film/biological buffer in the device, so that the bioaerosol adheres to the oil film, or passes through the oil film and directly enters the biological buffer;
    步骤四、生物气溶胶转水溶胶,利用检测装置的渐缩气道产生冲击力,或是第一泵浦吹开油膜翻转油膜上方捕捉的气溶胶至生物缓冲液中,变成水溶胶;Step 4: The biological aerosol is converted into a hydrosol, and the tapered airway of the detection device is used to generate an impact force, or the first pump blows the aerosol captured above the oil film and flips the oil film into the biological buffer to become a hydrosol;
    步骤五、浓缩质传,利用循环流道的设计,将生物缓冲液内的水溶胶全数流动到感测芯片与芯片上的探测分子捕捉结合;Step 5: Concentrating mass transfer, using the design of the circulating flow channel, all the hydrosols in the biological buffer flow to the sensing chip and the detection molecules on the chip are captured and combined;
    步骤六、检测,利用感测芯片上的探测分子捕捉结合,产生的讯号改变,进行目标生物气溶胶的浓度侦测。Step 6: Detecting, using the detection molecules on the sensing chip to capture and combine, and the resulting signal changes to detect the concentration of the target biological aerosol.
PCT/CN2021/091724 2021-04-30 2021-04-30 Bioaerosol detection device WO2022227076A1 (en)

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Citations (9)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20100186524A1 (en) * 2008-02-05 2010-07-29 Enertechnix, Inc Aerosol Collection and Microdroplet Delivery for Analysis
WO2012026963A2 (en) * 2010-08-23 2012-03-01 Darren Rubin Systems and methods of aerosol delivery with airflow regulation
US20120105839A1 (en) * 2009-07-11 2012-05-03 Enertechnix, Inc Progressive Cut-Size Particle Trap and Aerosol Collection Apparatus
CN102841001A (en) * 2012-09-20 2012-12-26 北京大学 Mineral oil film-based bio-aerosol sampling method
CN107192587A (en) * 2017-05-04 2017-09-22 北京大学 A kind of bioaerosol liquid phase acquisition method of portable big flow height enrichment
JP2019020372A (en) * 2017-07-20 2019-02-07 匡司 和田 Processing flow rate variable virtual impactor and pretreatment system for bioaerosol measuring instrument using processing flow rate variable virtual impactor
US20190154550A1 (en) * 2016-04-06 2019-05-23 The University Of Florida Research Foundation, Inc. Bioaerosol detection systems and methods of use
CN112266841A (en) * 2020-10-23 2021-01-26 东南大学 Biological sample processing chip device and processing method
TW202142864A (en) * 2020-05-05 2021-11-16 奇異平台股份有限公司 Bioaerosol detection apparatus

Patent Citations (9)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20100186524A1 (en) * 2008-02-05 2010-07-29 Enertechnix, Inc Aerosol Collection and Microdroplet Delivery for Analysis
US20120105839A1 (en) * 2009-07-11 2012-05-03 Enertechnix, Inc Progressive Cut-Size Particle Trap and Aerosol Collection Apparatus
WO2012026963A2 (en) * 2010-08-23 2012-03-01 Darren Rubin Systems and methods of aerosol delivery with airflow regulation
CN102841001A (en) * 2012-09-20 2012-12-26 北京大学 Mineral oil film-based bio-aerosol sampling method
US20190154550A1 (en) * 2016-04-06 2019-05-23 The University Of Florida Research Foundation, Inc. Bioaerosol detection systems and methods of use
CN107192587A (en) * 2017-05-04 2017-09-22 北京大学 A kind of bioaerosol liquid phase acquisition method of portable big flow height enrichment
JP2019020372A (en) * 2017-07-20 2019-02-07 匡司 和田 Processing flow rate variable virtual impactor and pretreatment system for bioaerosol measuring instrument using processing flow rate variable virtual impactor
TW202142864A (en) * 2020-05-05 2021-11-16 奇異平台股份有限公司 Bioaerosol detection apparatus
CN112266841A (en) * 2020-10-23 2021-01-26 东南大学 Biological sample processing chip device and processing method

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