Claims
- 1. An analyte detector for detecting an analyte, comprising:
a sensing assembly for sensing the analyte delivered by a carrier, the sensing assembly comprising:
a sensing unit constructed of an amplifying fluorescent polymer, the intensity of light emitted by the amplifying fluorescent polymer varying in response to interaction of the amplifying fluorescent polymer with molecules of the analyte delivered by the carrier; a source of excitation producing a medium that interacts with the amplifying fluorescent polymer to cause the amplifying fluorescent polymer to generate light; a detector receiving a medium generated by the amplifying fluorescent polymer, the detector outputting a signal indicative of the intensity of the light generated by the amplifying fluorescent polymer.
- 2. The analyte detector of claim 1, further comprising a capillary characterized as having an adsorption/desorption zone and a sensing zone with the sensing zone being downstream from the adsorption/desorption zone, the capillary in the adsorption/desorption zone selectively adsorbing and desorbing at least a portion of the molecules of the analyte delivered in the carrier, and the sensing unit of the sensing assembly being positioned in the sensing zone of the capillary for detection of molecules of the analyte.
- 3. The analyte detector of claim 2, further comprising means for maintaining the sensing zone of the capillary at a sequence of temperatures selectively elevating and depressing the temperature so as to reduce photodecomposition of the amplifying fluorescent polymer and/or increase the operational lifetime of the detector.
- 4. The analyte detector of claim 2, further comprising a first temperature control assembly for regulating the temperature of the adsorption/desorption zone of the capillary so as to enhance selective adsorption/desorption of the molecules of the analyte.
- 5. The analyte detector of claim 4, wherein the adsorption/desorption zone is maintained at a first temperature to effect adsorption of the molecules of the analyte and selectively elevated to a second temperature to effect desorption of the molecules of the analyte so as to form a pulse of desorbed molecules for passage to the sensing zone of the capillary by action of the carrier.
- 6. The analyte detector of claim 5, further comprising a converter assembly indicating the presence of vapors of the analyte delivered by the carrier at specific time intervals after receiving a timing signal indicative of the initiation of desorption of the molecules of the analyte from the adsorption/desorption zone and the signal from the detector indicating a change in emission intensity of the amplifying fluorescent polymer of the sensing unit at a predetermined time period after the reception of the timing signal by the converter assembly.
- 7. The analyte detector of claim 2, wherein the capillary is further characterized as having an equilibrium zone positioned between the adsorption/desorption zone and the sensing zone, and wherein the analyte detector further comprises a second temperature control assembly for maintaining the equilibrium zone at a substantially constant temperature so as to condition the desorbed molecules and the carrier to the temperature of the equilibrium zone.
- 8. The analyte detector of claim 7, wherein the analyte detector further comprises a third temperature control assembly for maintaining the sensing zone of the capillary at a substantially constant temperature.
- 9. The analyte detector of claim 2, wherein the capillary is further characterized as having a preconditioning zone positioned upstream of the adsorption/desorption zone for gathering and feeding the vapors of the analyte present in the sample to the adsorption/desorption zone of the capillary at a predetermined rate.
- 10. The analyte detector of claim 9, wherein the preconditioning zone of the capillary is constructed of fused silica having an interior surface coated with an effective amount of a low-retention coating to gather and feed the vapors of the analyte present in the sample to the adsorption/desorption zone of the capillary at the predetermined rate.
- 11. The analyte detector of claim 1, wherein the sensing unit includes a plurality of bands of different amplifying fluorescent polymers, each band being illuminated by a light source of distinct wavelength and modulation frequency, and each band having a width sufficient to capture the desorbed molecules while substantially preventing the desorbed molecules from passing over the band of amplifying fluorescent polymer without adsorption.
- 12. The analyte detector of claim 1, wherein the sensing unit includes a band of the amplifying fluorescent polymer, the band having a width sufficient to capture the desorbed molecules while substantially preventing the desorbed molecules from passing over the band of amplifying fluorescent polymer without adsorption.
- 13. The analyte detector of claim 12, wherein the width of the band of amplifying fluorescent polymer is in a range from about 0.5 mm to about 3 mm.
- 14. The analyte detector of claim 1, further comprising a first filter positioned between the source of excitation and the sensing unit so as to block light in a wavelength range corresponding to the wavelength of light generated by the amplifying fluorescent polymer, and to pass only the light over the range of wavelengths emitted by the source of excitation that result in excitation of the amplifying fluorescent polymer.
- 15. The analyte detector of claim 14, further comprising a second filter positioned between the sensing unit and the detector passing light generated by the amplifying fluorescent polymer and for blocking the medium emitted by the source of excitation.
- 16. The analyte detector of claim 1, wherein the source of excitation is modulated at a predetermined frequency, and a converter assembly demodulates the signal from the detector at the predetermined frequency so as to only recover signals in the signal from the detector which have been produced directly by the amplifying fluorescent polymer and indirectly from the medium produced by the source of excitation.
- 17. The analyte detector of claim 1, wherein the amplifying fluorescent polymer contains an effective amount of a plasticizing material so as to reduce photodecomposition of the amplifying fluorescent polymer and thereby extend the useful life of the amplifying fluorescent polymer.
- 18. The analyte detector of claim 17, wherein the plasticizing material is dioctylphthalate.
- 19. The analyte detector of claim 1, further comprising a housing having an inlet, enclosed sensing volume and an outlet, the sensing unit positioned in the housing, the analyte detector further comprising a pump drawing the carrier sequentially through the inlet, enclosed sensing volume and the outlet of the housing.
- 20. The analyte detector of claim 19, further comprising a means for maintaining the mass flow rate through the pump at a substantially constant rate.
- 21. The analyte detector of claim 19, further comprising means for maintaining the mass flow rate through the pump at a sequence of rates selectively elevating and depressing the mass flow rate.
- 22. The analyte detector of claim 1, further comprising a flow meter receiving the carrier and determining the flow rate of the carrier.
- 23. The analyte detector of claim 1, further comprising means for maintaining the temperature of the source of excitation at a predetermined temperature.
- 24. The analyte detector of claim 23, wherein the predetermined temperature of the source of excitation is maintained at a temperature of about 25° Celsius.
- 25. The analyte detector of claim 1, further comprising means for maintaining the temperature of the detector at a predetermined temperature.
- 26. The analyte detector of claim 25, wherein the predetermined temperature of the detector is maintained at a temperature of about 35° Celsius.
- 27. The analyte detector of claim 1, further comprising means for maintaining the excitation source at a sequence of temperatures.
- 28. The analyte detector of claim 1, further comprising means for maintaining the detector at a sequence of temperatures selectively elevating and depressing the temperature to increase the operational lifetime of the detector.
- 29. The analyte detector of claim 1, wherein the sensing unit includes a plurality of bands of amplifying fluorescent polymers, and each band having a width sufficient to capture the desorbed molecules while substantially preventing the desorbed molecules form passing over the band of amplifying fluorescent polymer without adsoprtion.
- 30. The analyte detector of claim 29, wherein all bands are excited by a single excitation source.
- 31. The analyte detector of claim 1, further comprising means for storing data indicative of signals output by the detector.
- 32. The analyte detector of claim 31, further comprising means for converting the signal from the detector into a digitized form.
- 33. A detector for detecting an analyte, comprising:
a sensing assembly for sensing the analyte delivered by a carrier, the sensing assembly comprising:
a sensing unit constructed of an amplifying fluorescentpolymer, the intensity of light emitted by the amplifying fluorescent polymer varying in response to interaction of the amplifying fluorescent polymer with molecules of the analyte delivered by the carrier; a source of excitation producing a medium that interacts with the amplifying fluorescent polymer to cause the amplifying fluorescent polymer to generate light; a light detector receiving a medium generated by the amplifying fluorescent polymer, the light detector outputting a signal indicative of the intensity of the light generated by the amplifying fluorescent polymer.
- 34. The detector of claim 33, further comprising a capillary characterized as having an adsorption/desorption zone and a sensing zone with the sensing zone being downstream from the adsorption/desorption zone, the capillary in the adsorption/desorption zone selectively adsorbing and desorbing at least a portion of the molecules of the analyte delivered in the carrier, and the sensing unit of the sensing assembly being positioned in the sensing zone of the capillary for detection of molecules of the analyte.
- 35. The detector of claim 34, further comprising means for maintaining the sensing zone of the capillary at a sequence of temperatures selectively elevating and depressing the temperature so as to reduce photodecomposition of the amplifying fluorescent polymer and/or increase the operational lifetime of the light detector.
- 36. The detector of claim 34, further comprising a first temperature control assembly for regulating the temperature of the adsorption/desorption zone of the capillary so as to enhance selective adsorption/desorption of the molecules of the analyte.
- 37. The detector of claim 36, wherein the adsorption/desorption zone is maintained at a first temperature to effect adsorption of the molecules of the analyte and selectively elevated to a second temperature to effect desorption of the molecules of the analyte so as to form a pulse of desorbed molecules for passage to the sensing zone of the capillary by action of the carrier.
- 38. The detector of claim 37, wherein the converter assembly indicates the presence of vapors of the analyte delivered by the carrier at specific time intervals after receiving a timing signal indicative of the initiation of desorption of the molecules of the analyte from the adsorption/desorption zone and the signal from the light detector indicating a change in emission intensity of the amplifying fluorescent polymer of the sensing unit at a predetermined time period after the reception of the timing signal by the converter assembly.
- 39. The detector of claim 34, wherein the capillary is further characterized as having an equilibrium zone positioned between the adsorption/desorption zone and the sensing zone, and wherein the detector further comprises a second temperature control assembly for maintaining the equilibrium zone at a substantially constant temperature so as to condition the desorbed molecules and the carrier to the temperature of the equilibrium zone.
- 40. The detector of claim 39, wherein the detector further comprises a third temperature control assembly for maintaining the sensing zone of the capillary at a substantially constant temperature.
- 41. The detector of claim 34, wherein the capillary is further characterized as having a preconditioning zone positioned upstream of the adsorption/desorption zone for gathering and feeding the vapors of the analyte present in the sample to the adsorption/desorption zone of the capillary at a predetermined rate.
- 42. The detector of claim 41, wherein the preconditioning zone of the capillary is constructed of fused silica having an interior surface coated with an effective amount of a low-retention coating to gather and feed the vapors of the analyte present in the sample to the adsorption/desorption zone of the capillary at the predetermined rate.
- 43. The detector of claim 33, wherein the sensing unit includes a plurality of bands of different amplifying fluorescent polymers coated onto an internal surface of the capillary, each band being illuminated by a light source of distinct wavelength and modulation frequency, and each band having a width sufficient to capture the desorbed molecules while substantially preventing the desorbed molecules from passing over the band of amplifying fluorescent polymer without adsorption.
- 44. The detector of claim 33, wherein the sensing unit includes a band of the amplifying fluorescent polymer coated onto an internal surface of the capillary, the band having a width sufficient to capture the desorbed molecules while substantially preventing the desorbed molecules from passing over the band of amplifying fluorescent polymer without adsorption.
- 46. The detector of claim 44, wherein the width of the band of amplifying fluorescent polymer is in a range from about 0.5 mm to about 3 mm.
- 47. The detector of claim 33, further comprising a first filter positioned between the source of excitation and the sensing unit so as to block light in a wavelength range corresponding to the wavelength of light generated by the amplifying fluorescent polymer, and to pass only the light over the range of wavelengths emitted by the source of excitation that result in excitation of the amplifying fluorescent polymer.
- 48. The detector of claim 46, further comprising a second filter positioned between the sensing unit and the light detector passing light generated by the amplifying fluorescent polymer and for blocking the medium emitted by the source of excitation.
- 49. The detector of claim 33, wherein the source of excitation is modulated at a predetermined frequency, and the converter assembly demodulates the signal from the detector at the predetermined frequency so as to only recover signals in the signal from the light detector which have been produced directly by the amplifying fluorescent polymer and indirectly from the medium produced by the source of excitation.
- 50. The detector of claim 33, wherein the amplifying fluorescent polymer contains an effective amount of a plasticizing material so as to reduce photodecomposition of the amplifying fluorescent polymer and thereby extend the useful life of the amplifying fluorescent polymer.
- 51. The detector of claim 49, wherein the plasticizing material is dioctylphthalate.
- 52. The detector of claim 33, further comprising a housing having an inlet, an enclosed sensing volume, and an outlet, the sensing unit positioned within the housing.
- 53. The detector of claim 51, wherein the detector further comprises a pump drawing the carrier sequentially through the inlet, the enclosed sensing volume and the outlet of the housing.
- 54. The detector of claim 51, further comprising a means for maintaining the mass flow rate through the pump at a substantially constant rate.
- 55. The detector of claim 51, further comprising a means for maintaining the mass flow rate through the pump at a sequence of rates selectively elevating and depressing the mass flow rate.
- 56. The detector of claim 33, further comprising a flow meter receiving the carrier and determining the flow rate of the carrier.
- 57. The detector of claim 33, further comprising means for maintaining the temperature of the source of excitation at a predetermined temperature.
- 58. The detector of claim 56, wherein the predetermined temperature of the source of excitation is maintained at a temperature of about 25° Celsius.
- 59. The detector of claim 33, further comprising means for maintaining the temperature of the light detector at a predetermined temperature.
- 60. The detector of claim 58, wherein the predetermined temperature of the light detector is maintained at a temperature of about 35° Celsius.
- 61. The detector of claim 33, further comprising means for maintaining the excitation source at a sequence of temperatures.
- 62. The detector of claim 33, further comprising means for maintaining the light detector at a sequence of temperatures selectively elevating and depressing the temperature so as increase the operational lifetime of the light detector and/or decrease the thermal noise present in the detector signal.
- 63. The detector of claim 33, further comprising a means for maintaining the sensing volume at a sequence of temperatures selectively elevating and depressing the temperature to increase the operational lifetime for at least one of the light detector, excitation source, components in the sensing volume, and components in contact with the sensing volume.
- 64. The detector of claim 33, wherein the sensing unit includes a plurality of bands of amplifying fluorescent polymers coated onto an internal surface of the capillary, and each band having a width sufficient to capture the desorbed molecules while substantially preventing the desorbed molecules form passing over the band of amplifying fluorescent polymer without adsoprtion.
- 65. The detector of claim 63, wherein all bands are excited by a single excitation source.
- 66. The detector of claim 33, further comprising means for storing data indicative of signals output by the detector.
- 67. The detector of claim 65, further comprising means for converting the signal from the light detector into a digitized form.
CROSS REFERENCE TO RELATED APPLICATIONS
[0001] The present patent application is a continuation of copending U.S. Ser. No. 09/978,491, filed Oct. 16, 2001, entitled “VAPOR SENSING INSTRUMENT FOR ULTRATRACE CHEMICAL DETECTION”, which claims priority to the provisional patent application identified by U.S. Ser. No. 60/241,068 filed on Oct. 17, 2000. The entire content of each of these applications is hereby incorporated herein by reference.
Provisional Applications (1)
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Number |
Date |
Country |
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60241068 |
Oct 2000 |
US |
Continuations (1)
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Number |
Date |
Country |
Parent |
09978491 |
Oct 2001 |
US |
Child |
10401051 |
Mar 2003 |
US |