Method for detecting the presence of microbes and determining their physiological status
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
C12Q-001/00
C12P-035/06
출원번호
US-0054419
(2002-01-22)
발명자
/ 주소
Powers, Linda S.
Lloyd, Christopher R.
출원인 / 주소
Microbiosystems, Limited Partnership
대리인 / 주소
Cornaby, K. S.
인용정보
피인용 횟수 :
15인용 특허 :
14
초록▼
Method and apparatus for the detection of microbes in liquids, in air and on non-living surfaces in which samples are exposed to electromagnetic radiation of specific energies capable of exciting various metabolites, cofactors and cellular and spore components, with the microbial cells to be sampled
Method and apparatus for the detection of microbes in liquids, in air and on non-living surfaces in which samples are exposed to electromagnetic radiation of specific energies capable of exciting various metabolites, cofactors and cellular and spore components, with the microbial cells to be sampled (and more specifically the excited metabolites, cofactors and or other cellular components) contained therein emit fluorescence that can be measured. The signal from the background and scattered excitation signals is removed from the fluorescence signals of the microbial components, the relative fluorescent signals of the intrinsic microbial components are required to lie within physiological ranges, and the amplitude of the background-corrected fluorescence signals used to enumerate the microbe content in the sample.
대표청구항▼
1. A method for the detection and enumeration of microbes comprising: a. exciting at least one intrinsic microbial fluorophore having a specific excitation range of electromagnetic radiation wavelength above 200 nm; whereby said intrinsic fluorophore in the microbes is excited to emit fluorescence
1. A method for the detection and enumeration of microbes comprising: a. exciting at least one intrinsic microbial fluorophore having a specific excitation range of electromagnetic radiation wavelength above 200 nm; whereby said intrinsic fluorophore in the microbes is excited to emit fluorescence; and b. detecting the signal intensities associated with the minima and maxima of the microbial fluorescence; and c. detecting the background intensities at the minima and maxima of the microbial fluorescence in the absence of excitation; and d. calculating the intensities of the reflectance and scattering at the maxima of the microbial fluorescence from the intensities of the background-subtracted minima with an appropriate algorithm; and e. subtracting the calculated reflected and scattered signal intensities and measured background intensities from the detected signals of the microbial fluorescence; thereby determining the number of microbes by the magnitude of the detected fluorescence from which background, reflectance, and scattering contributions have been subtracted. 2. The method as set forth in claim 1, wherein the ratios of multiple fluorescence signal intensities, from which measured background and calculated reflectance and scattering have been subtracted, are determined; whereby the detection of the physiological state of the microbes depends upon the requirement that the ratios of the background, scattering, and reflectance-corrected fluorescence signals lie within specified physiological ranges and that the enumeration of the microbes is determined by the magnitude of said detected signals the ratios of which lie within said expected ranges.3. The method as set forth in claim 1, wherein said microbial fluorophores are selected from the group consisting of nucleic acid polymers, tryptophan-containing proteins, tyrosine-containing proteins, adenosine triphosphate, calcium dipicolinate, reduced pyridine nucleotides, flavins, porphyrin-containing proteins, and other components excited in the 610-670 nm region.4. The method of claim 1, wherein the viable microbes to be detected include at least one of the following: bacteria, fungi, protozoa, and rickettsiae; and the intrinsic microbial fluorophores used to detect the microbes include at least one of the following: nucleic acid polymers, tyrosine-containing proteins, tryptophan-containing proteins, adenosine triphosphate, reduced pyridine nucleotides, flavins, porphyrin-containing proteins, and others excited in the 610-670 nm region.5. The method of claim 1, wherein non-viable microbes to be detected include at least one of the following: bacteria, fungi, protozoa, and rickettsiae; and the intrinsic microbial fluorophores used to detect the microbes include at least one of the following: nucleic acid polymers, tryptophan-containing proteins, tyrosine-containing proteins, reduced pyridine nucleotides, flavins, porphyrin-containing proteins, and others excited in the 610-670 nm region.6. The method of claim 1, wherein the microbes to be detected are bacterial endospores and the intrinsic fluorophores used to detect the endospores include at least one of the following: nucleic acid, polymers, tyrosine-containing proteins, tryptophan-containing proteins, calcium dipicolinic acid, and others excited in the 610-670 nm region.7. The method of claim 1, wherein the microbes to be detected include viruses, and the intrinsic fluorophores used to detect the viruses include at least one of the following: nucleic acid polymers, tyrosine-containing proteins, and tryptophan-containing proteins.8. A method for the detection and enumeration of microbes comprising: a. exciting multiple intrinsic microbial fluorophores with ultraviolet electromagnetic radiation having excitation wavelengths between 200 and 300 nm, whereby intrinsic fluorophores in any microbes present are excited to emit fluorescence, some of which is self-absorbed to excite other microbial fluorophores that in turn emit fluorescence and b. detecting the fluorescence signal intensities associated with the minima and maxima of the microbial fluorescence; and c. detecting the background intensities at the minima and maxima of the microbial fluorescence in the absence of excitation; and d. calculating the intensities of the reflectance and scattering at the maxima of the microbial fluorescence from the intensities of the background-subtracted minima with an appropriate algorithm: and e. subtracting the calculated reflected and scattered signal intensities and measured background signal intensities from the detected signals of the microbial fluorescence; and f. determining that the ratios of the detected fluorescence signals from which background, reflectance, and scattering contributions have been subtracted lie within physiological ranges, thereby determining the number of microbes by the magnitude of the detected fluorescence signals from which background, reflectance, and scattering contributions have been subtracted the ratios of which lie within physiological ranges. 9. The method as set forth in claim 8, wherein the intrinsic microbial fluorophores of said microbes include one or more of the group consisting of nucleic acid polymers, tryptophan-containing proteins, adenosine triphosphate, and calcium dipicolinate compounds.10. The method as set forth in claim 8, wherein secondary-excited microbial fluorophores include one or more of the group consisting of calcium dipicolinate, reduced pyridine nucleotides, flavins, porphyrin-containing proteins, cellular components excited in the 610-670 nm region, and the like.11. The method as set forth in claim 8, wherein the viable microbes to be detected include at least one of the following: bacteria, fungi, protozoa, and rickettsiae, and the intrinsic microbial fluorophores used to detect the microbes are selected from the group consisting of nucleic acid polymers, tyrosine-containing proteins, tryptophan-containing proteins, adenosine triphosphate, reduced pyridine nucleotides, flavins, porphyrin-containing proteins, and cellular components excited in the 610-670 nm region.12. The method of claim 8, wherein the non-viable microbes to be detected include at least one of the following: bacteria, fungi, protozoa, and rickettsiae; and the intrinsic microbial fluorophores used to detect the microbes are selected from the group consisting of nucleic acid polymers, tyrosine-containing proteins, tryptophan-containing proteins, reduced pyridine nucleotides, flavins, porphyrin-containing proteins, and cellular components excited in the 610-670 nm region.13. The method of claim 8, wherein the microbes to be detected are bacterial spores and the intrinsic fluorophores used to detect the spores include at least one of the following: nucleic acid polymers, tyrosine-containing proteins, tryptophan-containing proteins, calcium dipicolinic acid, and spore components excited in the 610-670 nm region.14. A method for the detection and enumeration of microbial proteinaceous toxins comprising: a. exciting at least one intrinsic fluorophore having a specific excitation range of electromagnetic radiation wavelength above 200 nm; whereby said fluorophores in the proteinaceous toxin present are excited to emit fluorescence; and b. detecting the fluorescence signal intensities associated with the minima and maxima of the excited fluorophores; and c. detecting the background intensities at the minima and maxima of the fluorescence in the absence of excitation; and d. calculating the intensities of the reflectance and scattering at the maxima of the fluorescence from the intensities of the background-subtracted minima with an appropriate algorithm; and e. subtracting the calculated reflected and scattered signal intensities and measured background intensities from the detected signal intensities of the fluorescence; thereby determining the amount of proteinaceous toxin by the magnit ude of said detected fluorescence from which background, reflectance, and scattering contributions have been subtracted. 15. The method as set forth in claim 14, wherein said microbe fluorophores are selected from the group consisting of tryptophan-containing proteins and tyrosine-containing proteins.16. A method for the detection and enumeration of spores and non-viable bacteria comprising: a. exciting at least one intrinsic microbial fluorophore having a specific excitation range of electromagnetic radiation wavelengths between 550 and 700 nm; whereby said intrinsic fluorophores present in the spores and non-viable bacteria are excited to emit fluorescence; and b. detecting the signal intensities associated with the minima and maxima of the fluorescence; and c. detecting the background intensities at the minima and maxima of the fluorophores in the absence of excitation; and d. calculating the intensities of the reflectance and scattering at the maxima of the microbial fluorescence from the intensities of the background-subtracted minima with an appropriate algorithm; and e. subtracting the calculated, reflected and scattered signal intensities and measured background intensities from the detected signal intensities of the excited microbial fluorescence; thereby enumerating the spores and non-viable bacteria by the magnitude of the detected fluorescence from which background, reflectance, and scattering contributions have been subtracted. 17. The method as set forth in claim 16, wherein the ratios of multiple detected, background-corrected signals are determined; whereby the distinction between spores and non-viable bacteria depends upon the requirement that the ratios of the background-corrected fluorescence signals lie within specified physiological ranges and that the enumeration of spores is determined by the magnitude of said detected signals, the ratios of which lie within said expected ranges.18. The method claim 16, wherein the intrinsic microbial fluorophores used to detect the non-viable bacteria and bacterial spores are selected from a group including flavins, porphyrin-containing proteins, and other components excited in the 610-670 nm region.19. The method of claim 16, wherein the non-viable bacteria and bacterial spores are detected on surfaces, inside paper envelopes, through paper, in solution and in aerosols.20. A method for the detection and enumeration of spores and non-viable bacteria comprising: a. excitation of multiple intrinsic microbial fluorophores with electromagnetic radiation having excitation wavelengths between 550 and 640 nm, whereby intrinsic fluorophores in any spores and non-viable bacteria present are excited to emit fluorescence, some of which is self-absorbed to excite other spore fluorophores that in turn emit fluorescence; b. detecting the fluorescence signal intensities associated with the minima and maxima of the microbial fluorescence; and c. detecting the background intensities at the minima and maxima of the intrinsic fluorophores in the absence of excitation; and d. calculating the intensities of the reflectance and scattering at the maxima of the microbial fluorescence from the intensities of the background-subtracted minima with an appropriate algorithm: and e. subtracting from the calculated, reflected and scattered signal intensities and measured background signal intensities from the detected signal intensities of the excited microbial fluorescence; and f. determining that the ratios of the detected, fluorescence signals from which background, reflectance, and scattering contributions have been subtracted lie within physiological ranges, thereby determining the number of bacterial spores and non-viable bacteria by the magnitude of the detected fluorescence signals from which background, reflectance, and scattering contributions have been subtracted, the ratios of which lie within physiological ranges. 21. The method as set forth in claim 20, wherein the intrinsic microbial fluorophores of said microbes include one or more of the group consisting of flavins, porphyrin-containing proteins, and other components excited in the 610-670 nm region.22. The method as set forth in claim 20, wherein secondary-excited microbial fluorophores include one or more of the group consisting of intrinsic components excited in the 610-680 nm region, and the like.23. The method of claim 20, wherein the non-viable bacteria and spores are detected on surfaces, inside paper envelopes, through paper, in solution and in aerosols.24. The method as set forth in claim 20, wherein the spores and non-viable bacteria are detected inside paper envelopes and the secondary-excited microbial fluorophores are excited by emissions from the excited paper products.
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