Real-time detection method and system for identifying individual aerosol particles
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G01N-031/00
B01D-059/44
B01D-059/00
출원번호
US-0916737
(2004-08-11)
등록번호
US-7260483
(2007-08-21)
발명자
/ 주소
Gard,Eric E.
Coffee,Keith R.
Frank,Matthias
Tobias,Herbert J.
Fergenson,David P.
Madden,Norm
Riot,Vincent J.
Steele,Paul T.
Woods,Bruce W.
출원인 / 주소
The Regents of the University of California
인용정보
피인용 횟수 :
8인용 특허 :
10
초록▼
An improved method and system of identifying individual aerosol particles in real time. Sample aerosol particles are collimated, tracked, and screened to determine which ones qualify for mass spectrometric analysis based on predetermined qualification or selection criteria. Screening techniques incl
An improved method and system of identifying individual aerosol particles in real time. Sample aerosol particles are collimated, tracked, and screened to determine which ones qualify for mass spectrometric analysis based on predetermined qualification or selection criteria. Screening techniques include one or more of determining particle size, shape, symmetry, and fluorescence. Only qualifying particles passing all screening criteria are subject to desorption/ionization and single particle mass spectrometry to produce corresponding test spectra, which is used to determine the identities of each of the qualifying aerosol particles by comparing the test spectra against predetermined spectra for known particle types. In this manner, activation cycling of a particle ablation laser of a single particle mass spectrometer is reduced.
대표청구항▼
We claim: 1. A method of identifying individual aerosol particles comprising: collimating sample aerosol particles into a particle beam; tracking the collimated particles of the particle beam; screening the tracked particles to determine which ones qualify for mass spectrometric analysis by satisfy
We claim: 1. A method of identifying individual aerosol particles comprising: collimating sample aerosol particles into a particle beam; tracking the collimated particles of the particle beam; screening the tracked particles to determine which ones qualify for mass spectrometric analysis by satisfying predetermined qualification criteria; desorbing/ionizing the qualifying particles in a bipolar mass spectrometer to produce positive and negative test spectra for each qualifying particle; and determining the identity of each desorbed/ionized particle by comparing the corresponding positive and negative test spectrum to spectra of the same respective polarity in a database of predetermined positive and negative spectra for known particle types to obtain a set of substantially matching spectra; and determining a best matching one of the known particle types having both a substantially matching positive spectrum and a substantially matching negative spectrum associated therewith from the set of substantially matching spectra. 2. The method of claim 1, further comprising pre-concentrating particles of a predetermined particle size range for collimation. 3. The method of claim 2, wherein a virtual impactor is used to pre-concentrate the particles in the predetermined particle size range. 4. The method of claim 1, wherein the sample aerosol particles are collimated into the particle beam by at least one of aerodynamically focusing and acoustically focusing the particles onto a central axis of the particle beam. 5. The method of claim 4, wherein the sample aerosol particles are collimated into the particle beam by both aerodynamically and acoustically focusing the particles onto the central axis of the particle beam. 6. The method of claim 1, wherein the collimated particles are tracked by determining the velocities thereof. 7. The method of claim 6, wherein the collimated particles are tracked by further determining the trajectories thereof. 8. The method of claim 7, wherein the collimated particles are tracked using an optical detector comprising at least two photo-sensors serially arranged along a flow path of the particle beam and capable of optically detecting particles passing thereby, said optical detector adapted to determine particle velocities from the time of flight between the photo-sensors and particle trajectories from the differences in detection response between the photo-sensors. 9. The method of claim 6, wherein the screening of the tracked particles comprises determining the size of a particle from a particle's velocity determination, and the qualification criteria includes having a particle size within a predetermined particle size range. 10. The method of claim 1, wherein the screening of the tracked particles comprises determining the symmetry of a particle, and the qualification criteria includes having a predetermined particle symmetry or asymmetry. 11. The method of claim 10, wherein particle symmetry is determined using a continuous wave laser and an opposing pair of photomultiplier (PMT) tubes, and from the scattered light detected by the opposing pair of photomultiplier (PMT) tubes when a particle crosses the continuous wave laser. 12. The method of claim 1, wherein the screening of the tracked particles comprises determining the shape of a particle, and the qualification criteria includes having a predetermined particle shape. 13. The method of claim 12, wherein the shape of a particle is determined using a multi-channel, spatially-resolved photo-sensor array adapted to measure at least two-dimensional optical scattering patterns produced from light scattered by a passing particle. 14. The method of claim 13, wherein the at least two-dimensional optical scattering patterns are produced from the scattered light within a 4π solid angle. 15. The method of claim 1, wherein the screening of the tracked particles comprises determining whether an individual particle is a biological particle, and the qualification criteria includes exhibiting fluorescence when exposed to radiation in a predetermined wavelength range. 16. The method of claim 1, wherein the screening of the tracked particles comprises determining the amount of charge on a particle, and the qualification criteria includes having a predetermined amount of charge indicative of a chemical composition of interest. 17. The method of claim 1, wherein the screening of the tracked particles comprises at least one of: determining the size of an individual particle, with the qualification criteria including having a particle size within a predetermined particle size range; determining the symmetry of an individual particle, with the qualification criteria including having a predetermined particle symmetry or asymmetry; determining the shape of an individual particle, with the qualification criteria including having a predetermined particle shape; determining whether an individual particle is a biological particle, with the qualification criteria including exhibiting fluorescence when exposed to radiation in a predetermined wavelength range; and determining the amount of charge on a particle, and the qualification criteria includes having a predetermined amount of charge indicative of a chemical composition of interest. 18. The method of claim 1, wherein the comparison of each test spectrum to spectra of the same respective polarity in the database produces a similarity score for each predetermined spectrum, with the set of substantially matching spectra based on a predetermined similarity score threshold. 19. The method as in claim 18, wherein the best matching one of the known particle types has associated therewith, for at least one of the substantially matching positive and negative spectra, the highest order similarity score of all substantially matching spectra of the same respective polarity. 20. The method as in claim 19, wherein the best matching one of the known particle types has associated therewith a substantially matching positive spectrum with the highest order similarity score of all substantially matching positive spectra. 21. The method as in claim 19, wherein the best matching one of the known particle types has associated therewith a substantially matching negative spectrum with the highest order similarity score of all substantially matching negative spectra. 22. The method as in claim 18, wherein the comparison of each test spectrum to the database includes converting each test spectrum into a corresponding test spectrum vector, and vector multiplying the test spectrum vector with a transpose of a predetermined spectrum vector of the same respective polarity to calculate the similarity score. 23. A method of identifying individual aerosol particles comprising: pre-concentrating a predetermined particle size range of sample aerosol particles; collimating the pre-concentrated particles into a particle beam by at least one of aerodynamically focusing and acoustically focusing the particles onto a central axis of the particle beam; tracking the collimated particles using an optic detector comprising at least two photo-sensors serially arranged along a flow path of the particle beam and capable of optically detecting particles passing thereby, said optical detector adapted to determine particle velocities from the time of flight between the photo-sensors and particle trajectories from the differences in detection response between the photo-sensors; screening the tracked particles to determine which ones qualify for mass spectrometric analysis by satisfying predetermined qualification criteria, said screening comprising at least one of: determining the size of an individual particle, with the qualification criteria including having a particle size within a predetermined particle size range; determining the symmetry of an individual particle, with the qualification criteria including having a predetermined particle symmetry or asymmetry; determining the shape of an individual particle, with the qualification criteria including having a predetermined particle shape; determining whether an individual particle is a biological particle, with the qualification criteria including exhibiting fluorescence when exposed to radiation in a predetermined wavelength range, and determining the amount of charge on a particle, with the qualification criteria including having a predetermined amount of charge indicative of a chemical composition of interest; desorbing/ionizing the qualifying particles in a bipolar mass spectrometer to produce positive and negative test spectra for each qualifying particle; and determining the identity of each desorbed/ionized particle by comparing the corresponding positive and negative test spectrum to spectra of the same respective polarity in a database of predetermined positive and negative spectra for known particle types to obtain a set of substantially matching spectra; and determining a best matching one of the known particle types having both a substantially matching positive spectrum and a substantially matching negative spectrum associated therewith from the set of substantially matching spectra. 24. A system for determining the identities of individual aerosol particles comprising: a collimating module adapted to produce a particle beam from sample aerosol particles; a particle tracking module adapted to track the collimated particles of the particle beam; screening means for determining which ones of the tracked particles qualify for mass spectrometric analysis by satisfying predetermined qualification criteria; a single particle bipolar mass spectrometer having an ablation laser for desorbing/ionizing the qualifying particles to produce positive and negative test spectra for each qualifying particle; and analyzing means for determining the identity of each desorbed/ionized particle, wherein the analyzing means comprises: a data storage medium; a database of predetermined mass spectra for known particle types stored on the data storage medium; and a data processor adapted to determine the identity of each desorbed/ionized particle by: comparing the corresponding positive and negative test spectrum of the particle to spectra of the same respective polarity in a database of predetermined positive and negative spectra for known particle types to obtain a set of substantially matching spectra; and determining a best matching one of the known particle types having both a substantially matching positive spectrum and a substantially matching negative spectrum associated therewith from the set of substantially matching spectra. 25. The system of claim 24, further comprising a pre-concentrating module adapted to pre-concentrate a predetermined particle size range for collimation. 26. The system of claim 25, wherein the pre-concentrating module is a virtual impactor. 27. The system of claim 24, wherein the collimating module comprises at least one of an aerodynamic focusing module having a converging nozzle and an acoustic focusing module, with each module adapted to focus the particles onto a central axis of the particle beam. 28. The system of claim 27, wherein the collimating module comprises both the aerodynamic focusing module and the acoustic focusing module. 29. The system of claim 24, wherein the particle tracking module is adapted to determine the velocities of the collimated particles. 30. The system of claim 29, wherein the particle tracking module is adapted to further determine the trajectories of the collimated particles. 31. The system of claim 30, wherein the particle tracking module comprises an optical detector comprising at least two photo-sensors serially arranged along a flow path of the particle beam with each capable of optically detecting particles passing thereby, said tracking module adapted to determine particle velocities from the time of flight between the photo-sensors and particle trajectories from the difference in detection response between the photo-sensors. 32. The system of claim 29, wherein the screening means includes means for determining the size of a particle from the particle velocity determined by the particle tracking module, and an associated qualification criteria includes having a particle size within a predetermined particle size range. 33. The system of claim 24, wherein the screening means includes means for determining the symmetry of a particle, and an associated qualification criteria includes having a predetermined particle symmetry or asymmetry. 34. The system of claim 33, wherein the symmetry screening module comprises a continuous wave laser and an opposing pair of photomultiplier (PMT) tubes, and is adapted to determine particle symmetry from the scattered light detected by the opposing pair of photomultiplier (PMT) tubes when a particle crosses the continuous wave laser. 35. The system of claim 24, wherein the screening means includes means for determining the shape of a particle, and an associated qualification criteria includes having a predetermined particle shape. 36. The system of claim 35, wherein the means for determining the shape of a particles comprises a multi-channel, spatially-resolved photo-sensor array adapted to measure at least two-dimensional optical scattering patterns produced from light scattered by a passing particle. 37. The system of claim 36, wherein the at least two-dimensional optical scattering patterns are produced from the scattered light within a 4π solid angle. 38. The system of claim 24, wherein the screening means includes means for determining whether a particle is a biological particle, and an associated qualification criteria includes exhibiting fluorescence when exposed to a radiation in a predetermined wavelength range. 39. The system of claim 24, wherein the screening means includes means for determining the amount of charge on a particle, and the qualification criteria includes having a predetermined amount of charge indicative of a chemical composition of interest. 40. The system of claim 24, wherein the screening means comprises at least one of: means for determining a particle size of an individual particle from its velocity determination, with an associated qualification criteria including having a particle size within a predetermined particle size range; means for determining the symmetry of an individual particle, with an associated qualification criteria including having a predetermined particle symmetry or asymmetry; means for determining the shape of an individual particle, with an associated qualification criteria including having a predetermined particle shape; means for determining whether the individual particle is a biological particle, with an associated qualification criteria including exhibiting fluorescence when exposed to radiation in a predetermined wavelength range; and means for determining the amount of charge on a particle, with the qualification criteria including having a predetermined amount of charge indicative of a chemical composition of interest. 41. The system of claim 24, wherein the analyzing means comprises: a data storage medium; a database of predetermined mass spectra for known particle types stored on the data storage medium; and a data processor adapted to determine the identity of each desorbed/ionized particle by comparing the corresponding test spectrum to the predetermined mass spectra for the known particle types. 42. The system of claim 24, wherein upon comparing each test spectrum to spectra of the same respective polarity in the database, the data processor produces a similarity score for each predetermined spectrum, with the set of substantially matching spectra based on a predetermined similarity score threshold. 43. The system of claim 42, wherein the best matching one of the known particle types has associated therewith, for at least one of the substantially matching positive and negative spectra, the highest order similarity score of all substantially matching spectra of the same respective polarity. 44. The system of claim 43, wherein the best matching one of the known particle types has associated therewith a substantially matching positive spectrum with the highest order similarity score of all substantially matching positive spectra. 45. The system of claim 43, wherein the best matching one of the known particle types has associated therewith a substantially matching negative spectrum with the highest order similarity score of all substantially matching negative spectra. 46. The system of claim 42, wherein the comparison of each test spectrum to the database includes converting each test spectrum into a corresponding test spectrum vector, and vector multiplying the test spectrum vector with a transpose of a predetermined spectrum vector of the same respective polarity to calculate the similarity score. 47. A system for identifying individual aerosol particles comprising: a particle concentrator module for pre-concentrating a predetermined particle size range of sample aerosol particles; a collimating module having at least one of an aerodynamic focusing component and an acoustic focusing component, for producing a collimated particle beam from sample aerosol particles by focusing the particles onto a central axis of the particle beam; a particle tracking module having an optic detector comprising at least two photo-sensors serially arranged along a flow path of the particle beam and capable of optically detecting particles passing thereby, said optical detector adapted to determine particle velocities from the time of flight between the photo-sensors and particle trajectories from the differences in detection response between the photo-sensors; screening means for determining which ones of the tracked particles qualify for mass spectrometric analysis by satisfying predetermined qualification criteria, the screening means comprising at least one of: means for determining the size of an individual particle, with the qualification criteria including having a particle size within a predetermined particle size range; means for determining the symmetry of an individual particle, with the qualification criteria including having a predetermined particle symmetry or asymmetry; means for determining the shape of an individual particle, with the qualification criteria including having a predetermined particle shape; means for determining whether an individual particle is a biological particle, with the qualification criteria including exhibiting fluorescence when exposed to radiation in a predetermined wavelength range, and means for determining the amount of charge on a particle, with the qualification criteria including having a predetermined amount of charge indicative of a chemical composition of interest; a single particle bipolar mass spectrometer having an ablation laser for desorbing/ionizing the qualifying particles to produce positive and negative test spectra for each qualifying particle; and analyzing means for determining the identity of each desorbed/ionized particle by comparing the corresponding positive and negative test spectrum to spectra of the same respective polarity in a database of predetermined positive and negative spectra for known particle types to obtain a set of substantially matching spectra; and determining a best matching one of the known particle types having both a substantially matching positive spectrum and a substantially matching negative spectrum associated therewith from the set of substantially matching spectra.
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