An apparatus and method employing a plurality of light emitting devices which each can get light through a respective optical fiber toward a respective sample of a plurality of samples in a time-staggered manner. Light is generated in each of the samples at different times consistent with the times
An apparatus and method employing a plurality of light emitting devices which each can get light through a respective optical fiber toward a respective sample of a plurality of samples in a time-staggered manner. Light is generated in each of the samples at different times consistent with the times at which light is irradiated onto the sample. A single detector is used to detect the lights emitted from the plurality of samples at these different times. A plurality of bifurcated optical cable are coupled to the light emitting devices and single light detector, and the integrated end of each bifurcated cable acts as the light emitting port and light detecting port. Multiple targets can be detected from each of the plurality of samples in the same manner by providing an apparatus and method employing a different plurality of light emitting devices and single detector for each target to be detected.
대표청구항▼
An apparatus and method employing a plurality of light emitting devices which each can get light through a respective optical fiber toward a respective sample of a plurality of samples in a time-staggered manner. Light is generated in each of the samples at different times consistent with the times
An apparatus and method employing a plurality of light emitting devices which each can get light through a respective optical fiber toward a respective sample of a plurality of samples in a time-staggered manner. Light is generated in each of the samples at different times consistent with the times at which light is irradiated onto the sample. A single detector is used to detect the lights emitted from the plurality of samples at these different times. A plurality of bifurcated optical cable are coupled to the light emitting devices and single light detector, and the integrated end of each bifurcated cable acts as the light emitting port and light detecting port. Multiple targets can be detected from each of the plurality of samples in the same manner by providing an apparatus and method employing a different plurality of light emitting devices and single detector for each target to be detected. d carriage and having thereon said first set of three calibrating points corresponding to said three point light sources; and a second calibrating plate located at said second distance from said end of said carriage for obtaining thereon said second set of three projective points from said three point light beams passing out of said end of said carriage and having thereon said second set of three calibrating points corresponding to said three point light sources. 6. The apparatus according to claim 5 wherein said first calibrating plate and said second calibrating plate are made of transparent material. 7. The apparatus according to claim 1 wherein said end of said carriage is provided for accommodating an object to be scanned. 8. A method of calibrating a reflective lens on a carriage for being used in manufacturing an image scanning apparatus, comprising the steps of: fixing said carriage to a specific position; installing three point light sources on three lined-up positions respectively; at a first distance from one end of said carriage, defining a first set of three calibrating points with respect to said three point light sources; at a second distance from said end of said carriage, defining a second set of three calibrating points with respect to said three point light sources; causing each of said three point light sources to transmit along corresponding one of predetermined light paths of said image scanning apparatus into said carriage and passing out from said end of said carriage so as to obtain a first set of three projective points and a second set of three projective points at the first and the second distance from said end of said carriage respectively; and adjusting an angle and a position of said reflective lens on said carriage for matching each of said projective points with a corresponding one of said calibrating points so as to achieve a calibrating function. 9. The method according to claim 8 wherein said end of said carriage is provided for accomodating an object to be scanned. 10. The method according to claim 8 wherein an image sensing device of said image scanning apparatus travels over said three lined-up positions. 11. The method according to claim 8 wherein said light paths of said image scanning apparatus extends to said three lined-up positions. 12. The method according to claim 8 wherein said first set of three projective points and said first set of three calibrating points are disposed on a first calibrating plate located at said first distance from said end of said carriage. 13. The method according to claim 8 wherein said second set of three projective points and said second set of three calibrating points are disposed on a second calibrating plate located at said second distance from said end of said carriage. 14. An apparatus adapted to be used in manufacturing an image scanning apparatus for calibrating a reflective lens on a carriage, comprising: a fixing unit for fixing said carriage; a movable point light source located at three lined-up positions alternately, for alternately emitting a point light beam from each of said three lined-up positions to transmit the point light beam along corresponding one of predetermined light paths of said image scanning apparatus into said carriage and pass out of said carriage from one end of the carriage; a first calibrating piece, located at a first distance from said end of said carriage, for obtaining thereon a first set of three projective points from said three point light beams passing out of said end of said carriage and having thereon a first set of three calibrating points corresponding to said three point light beams from said three lined-up positions; and a second calibrating piece, located at a second distance from said end of said carriage, for obtaining thereon a second set of three projective points from said three point light beams passing out of said end of said carriage and having thereon a second set of three cal ibrating points correspond to said three point light beams from said three lined-up positions, and for matching each of said projective points on said calibrating pieces with a corresponding one of said calibrating points by adjusting an angle and a position of said reflective lens on said carriage so as to achieve a calibrating function. 15. The apparatus according to claim 14 wherein an image sensing device of said image scanning apparatus travels over said three lined-up positions. 16. The apparatus according to claim 14 wherein said light paths of said image scanning apparatus extends to said three lined-up positions. 17. The apparatus according to claim 14 wherein said end of said carriage is provided for accomodating an object to be scanned. 18. The apparatus according to claim 14 wherein said point light source is a laser light source. 19. The apparatus according to claim 14 wherein said first calibrating piece is in a form of plate. 20. The apparatus according to claim 14 wherein said second calibrating piece is in a form of plate. 21. The apparatus according to claim 14 wherein said first calibrating piece and said second calibrating piece are made of transparent material. 22. A method of calibrating a reflective lens on a carriage for being used in manufacturing an image scanning apparatus, comprising the steps of: fixing said carriage to a certain position; installing a movable point light source on each of three lined-up positions alternately, for alternately emitting three point light beams from said three lined-up positions; at a first distance from one end of said carriage, defining a first set of three calibrating points with respect to said three point light beams from said three lined-up positions; at a second distance from said end of said carriage, defining a second set of three calibrating points with respect to said three point light beams from said three lined-up positions; causing each of said point light beams to transmit along corresponding one of predetermined light paths of said image scanning apparatus into said carriage and pass out from said end of said carriage so as to obtain a first set of three protective points and a second set of three projective points at said first and second distance from said end of said carriage; and adjusting an angle and a position of said reflective lens on said carriage for matching each of said projective points with a corresponding one of said calibrating points so as to achieve a calibrating function. 23. The method according to claim 22 wherein an image sensing device of said scanning apparatus travels over said three lined-up positions. 24. The method according to claim 22 wherein said light paths of said image scanning apparatus extends to said three lined-up positions. 25. The method according to claim 22 wherein said end of said carriage is provided for accomodating an object to be scanned. 26. An apparatus adapted to be used in manufacturing an image scanning apparatus for calibrating a reflective lens, wherein said image scanning apparatus includes said reflective lens and a mirror arranged inside a carriage, said apparatus comprising: a fixing unit for fixing said carriage; a point light source located at a position for emitting point light beam to be transmitted along a predetermined light path of said image scanning apparatus into said carriage and pass out of said carriage from one end of the carriage; and a calibrating device having, at a first distance from said end of said carriage, a first projective point from said point light beam passing out of said end of said carriage and a first calibrating point corresponding to said point light source, and having, at a second distance from said end of said carriage, a second projective point from said point light beam passing out of said end of said carriage and a second calibrating point corresponding to said point light source, for matching each of said projective points on said calibrat ing device with a corresponding one of said calibrating points by adjusting an angle and a position of said reflective lens on said carriage so as to achieve a calibrating function, wherein said calibrating device comprises: a first calibrating plate located at said first distance from said end of said carriage for obtaining thereon said first projective point from said light beam passing out of said end of said carriage, and having thereon said first calibrating point corresponding to said point light source; and a second calibrating plate located at said second distance from said end of said carriage for obtaining thereon said second projective point from said light beam passing out of said end of said carriage, and having thereon said second calibrating point corresponding to said light source. 27. The apparatus according to claim 26 wherein said point light source is a laser light source. 28. An apparatus adapted to be used in manufacturing an image scanning apparatus for calibrating a reflective lens on a carriage, comprising: a fixing unit for fixing said carriage; two point light sources located at two specific positions respectively, for respectively emitting point light beams to be transmitted along corresponding one of predetermined light paths of said image scanning apparatus into said carriage and pass out of said carriage from one end of said carriage; a first calibrating piece located at a first distance from said end of said carriage for obtaining thereon a first set of two projective points from said two point light beams passing out of said end of said carriage, wherein a third projective point lined up with said first set of two projective points is obtained by operating said first set of two projective points to develop a first set of three projective points, and for defining a first set of three calibrating points on said first calibrating piece to be compared to said first set of three projective points; and a second calibrating piece located at a second distance from said end of said carriage for obtaining thereon a second set of two projective points from said two point light beams passing out of said end of said carriage, wherein another third projective point lined up with said second set of two projective points is obtained by operating said second set of two projective points to develop a second set of three projective points, and for defining a second set of thee calibrating points on said second calibrating piece to be compared to said second set of three projective points, for matching each of said projective points on said calibrating pieces with a corresponding one of said calibrating points by adjusting an angle and a position of said reflective lens on said carriage so as to achieve a calibrating function. 29. The apparatus according to claim 28 wherein an image sensing device of said scanning apparatus travels over said two specific positions. 30. The apparatus according to claim 28 wherein said light paths of said image scanning apparatus extends to said two specific positions. 31. The apparatus according to claim 28 wherein said end of said carriage is provided for accommodating an object to be scanned. 32. The apparatus according to claim 28 wherein said third projective point of said first set of three projective points is obtained by an extrapolation. 33. The apparatus according to claim 28 wherein said third projective point of said first set of three projective points is obtained by an interpolation. 34. The apparatus according to claim 28 wherein said another third projective point of said second set of three projective points is obtained by an extrapolation. 35. The apparatus according to claim 28 wherein said another third projective point of said second set of three projective points is obtained by an interpolation. 36. A method of calibrating a reflective lens on a carriage for being used in manufacturing an image scanning apparatus, comprising the steps of: fixing said carriage to a certain position; installing two point light sources on two specific positions respectively; causing each of said two point light sources to transmit along corresponding one of predetermined light paths of said image scanning apparatus into said carriage and pass out from one end of said carriage so as to obtain a first set of two projective points at a first distance from said end of said carriage and a second set of two projective points at a second distance from said end of said carriage; obtaining a third projective point lined up with said first set of two projective points by operating said first set of two projective points to develop a first set of three projective points; defining a first set of three calibrating points to be compared to said first set of three projective points; obtaining another third projective point lined up with said second set of two projective points by operating said second set of two projective points to develop a second set of three projective points; defining a second set of three calibrating points to be compared to said second set of three projective points; and adjusting an angle and a position of said reflective lens on said carriage for matching each of said projective points with a corresponding one of said calibrating points so as to achieve a calibrating function. 37. The method according to claim 36 wherein an image sensing device of said image scanning apparatus travels over said two specific positions. 38. The method according to claim 36 wherein said light paths of said image scanning apparatus extends to said two specific positions. 39. The method according to claim 36 wherein said end of said carriage is provided for accommodating an object to be scanned. 40. The method according to claim 36 wherein said third projective point of said first set of three projective points is obtained by an extrapolation. 41. The method according to claim 36 wherein said third projective point of said first set of three projective points is obtained by an interpolation. 42. The method according to claim 36 wherein said another third projective point of said second set of three projective points is obtained by an extrapolation. 43. The method according to claim 36 wherein said another third projective point of said second set of three projective points is obtained by an interpolation.
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (77)
Fratantoni Joseph C. (Rockville MD) Poindexter Betty J. (Kensington MD), Adaptation of microtiter plate technology to measurement of platelet aggregation.
Bonfiglio Paolo (Bareggio ITX) Calzi Claudio (Milan ITX), Analytical photometer, in particular multi-channel, applied to a centrifugal system adapted to perform practically simul.
Sonne Vesa (Vanhalinna FIX) Varjonen Markku (Turku FIX) Lehtinen Kauko (Raisio FIX) Yrjnen Tapio (Turku FIX) Jrnstrm Stefan (Pargas FIX), Arrangement for counting liquid scintillation samples on bottom-window multi-well sample plates.
Clark Frederic L. (Plano TX) Clift Gilbert (Mesquite TX) Hendrick Kendall B. (Southlake TX) Kanewske ; III William J. (Dallas TX) Lagocki Peter A. (Park Ridge IL) Martin Richard R. (Irving TX) Mitche, Automated continuous and random access analytical system.
Andrews Jeffrey P. ; O'Keefe Christian V. ; Scrivens Brian G. ; Pope Willard C. ; Hansen Timothy ; Failing Frank L., Automated optical reader for nucleic acid assays.
Weyrauch Bruce (Newman Lake WA) Schmidt Leon (Spokane WA) Cutler Dan (Spokane WA), Capacitive sensing system and wash/alignment station for a chemical analyzer.
Packard Lyle E. (Hinsdale IL) Polic Edward F. (Lyle IL) Cavanaugh ; Jr. Robert E. (La Grange Park IL), Data analyzing system having provision for optimizing counting conditions and thus improving statistical counting validi.
Hafeman Dean G. (Hillsborough CA) Parce John W. (Palo Alto CA) McConnell Harden M. (Stanford CA), Device for photoresponsive detection and discrimination.
Kanewske ; III William J. (Dallas TX) Vaught James A. (Euless TX) Vickstrom Richard L. (Algonquin IL) Clark Frederic L. (Plano TX) Clift Gilbert (Mesquite TX) Hendrick Kendall B. (Southlake TX) Lagoc, Injection molding a plastic assay cuvette having low birefringence.
Tiffany Thomas (E. 1305 56th Spokane WA 99223) Weyrauch Bruce (N. 13707 Coman Rd. Newman Lake WA 99025) Thayer Phillip (N. 8617 Seven Mile Rd. Nine Mile Falls WA 99026), Method and apparatus for conducting multiple chemical assays.
Kolehmainen Seppo (P.O. Box 2805 Titusville FL 32780) Tarkkanen Veikko (Krijgersberglaan 25 6371 CA Schaesberg NLX 4), Method and apparatus for measurement of samples by luminescence.
Tguunanen Jukka (Helsinki FIX) Kainiemi Aimo (Espoo FIX), Method for photometrically measuring light transmitted to and through cuvettes disposed in a row.
Fish Falk (5 Kashani Street Tel Aviv ILX 69499) Herzberg Max (Moshay Sataria Rehovot ILX 73272) Ritterband Menachem (25 E. Ben Yehuda Street Rehovot ILX 70650), Method for the determination and measurements of more than one unknown material in a single surface of a multianalytic a.
Hanley Kathleen A. (Gurnee IL) Hofferbert A. David (Grafton WI) Lee Helen H. (Lake Forest IL) Pepe Curtis J. (McHenry IL) Zurek Thomas F. (River Forest IL), Method of minimizing contamination in amplification reactions using a reaction tube with a penetrable membrane.
Blumenfeld Walter (Airville PA) Berndt Klaus W. (Stewartstown PA), Methods and apparatus for detecting bacterial growth by spectrophotometric sampling of a fiber-optic array.
Manns Roy L. (Marshfield Hills MA) Kolb Alfred J. (Madison CT) Effertz Bernard S. (Meriden CT), Microplate farming wells with transparent bottom walls for assays using light measurements.
Manns Roy L. (Marshfield Hills MA) Kolb Alfred J. (Madison CT) Effertz Bernard S. (Meriden CT), Microplate forming wells with transparent bottom walls for assays using light measurements.
Klein Gerald L. (Edmonds WA) Russell Gene D. (Seattle WA) Day Steven R. (Bothell WA) Liebermann Jerrold D. (Seattle WA), Photodensitometer for minimizing the refractive effects of a fluid sample.
Gerlier Jean-Pierre (Saint-Maur-les-Fosses FRX) Augier Jacques (Paris FRX), Photometer with automatic test sample selection, scanning and analysis system.
Holen, James T.; Hicaro, Jr., Enrique; Putterman, Caryn G.; Huang, Tung-Ming; Merkh, Carl W., Reaction cartridge and carousel for biological sample analyzer.
Warner Brian D. (Martinez CA) Nordell Benjamin T. (Belmont CA) Richardson Bruce J. (Los Gatos CA) El-Hage Amer (Menlo Park CA), Releasable multiwell plate cover.
VanCauter Gustaaf C. (Middletown CT) Osten Donald E. (Bolingbrook IL) Tomisek John D. (Lombard IL), Scintillation counting system for in-situ measurement of radioactive samples in a multiple-well plate.
Chow Calvin Y. H. (Portola Valley CA) Humphries Gillian M. (Los Altos CA) Kung Viola T. (Menlo Park CA) Lacy Michael M. (Ben Lomand CA), Single source multi-site photometric measurement system.
Chow Calvin Y. H. (Portola Valley CA) Humphries Gillian M. (Los Altos CA) Kung Viola T. (Menlo Park CA) Lacy Michael M. (Ben Lomand CA) Hayter Paul (Los Altos CA), Single source multi-site photometric measurement system.
Merkh Carl W. (Lindenhurst IL) Defreese James D. (Wildwood IL) Durley ; III ; deceased Benton A. (late of Antioch IL by Robert W. Durley ; executrix), Test array for performing assays.
Bird, Dylan Hilmer; Ching, Jesus; Johnson, Bruce A.; Moravick, Keith E.; Richardson, Bruce, Apparatus and methods for integrated sample preparation, reaction and detection.
Bird, Dylan Hilmer; Ching, Jesus; Johnson, Bruce A.; Moravick, Keith E.; Richardson, Bruce, Apparatus and methods for integrated sample preparation, reaction and detection.
Bird, Dylan Hilmer; Ching, Jesus; Johnson, Bruce A.; Moravick, Keith E.; Richardson, Bruce, Apparatus and methods for integrated sample preparation, reaction and detection.
Bird, Dylan Hilmer; Ching, Jesus; Johnson, Bruce A.; Moravick, Keith E.; Richardson, Bruce, Apparatus and methods for integrated sample preparation, reaction and detection.
Wilson, Brian D.; Anderson, David L.; Davis, Matthew S.; Erickson, Matthew D.; Johnson, Alan N.; Maurer, Garrick A.; Rosen, Michael J.; Sauerburger, Mark F.; Schmidt, Daniel R.; Wiltsie, Joshua D., Assay cartridge with reaction well.
Ammann, Kelly G.; Burns, Ralph E.; Hansberry, Ernest V.; Horner, Glenn A.; Jakub, Cheryl A.; Kling, John E.; Nieglos, Donald J.; Schneider, Robert E.; Smith, Robert J., Automated analyzer for performing a nucleic acid-based assay.
Ochranek, Brian L.; Arnquist, David C.; Oonuma, Takehiko; Tahara, Hirotoshi; Sato, Naoto; Smith, Bradley P., Automated diagnostic analyzers having rear accessible track systems and related methods.
Ochranek, Brian L.; Arnquist, David C.; Oonuma, Takehiko; Tahara, Hirotoshi; Sato, Naoto, Automated diagnostic analyzers having vertically arranged carousels and related methods.
Ochranek, Brian L.; Arnquist, David C.; Oonuma, Takehiko; Tahara, Hirotoshi; Sato, Naoto, Automated diagnostic analyzers having vertically arranged carousels and related methods.
Ammann, Kelly G.; Burns, Ralph E.; Hansberry, Ernest V.; Horner, Glenn A.; Jakub, Cheryl A.; Kling, John E.; Nieglos, Donald J.; Schneider, Robert E.; Smith, Robert J., Automated process for detecting the presence of a target nucleic acid in a sample.
Ammann, Kelly G.; Burns, Ralph E.; Hansberry, Ernest V.; Horner, Glenn A.; Jakub, Cheryl A.; Kling, John E.; Nieglos, Donald J.; Schneider, Robert E.; Smith, Robert J., Automated process for detecting the presence of a target nucleic acid in a sample.
Ammann, Kelly G.; Burns, Ralph E.; Hansberry, Ernest V.; Horner, Glenn A.; Jakub, Cheryl A.; Kling, John E.; Nieglos, Donald J.; Schneider, Robert E.; Smith, Robert J., Automated process for detecting the presence of a target nucleic acid in a sample.
Ammann,Kelly G.; Burns,Ralph E.; Hansberry,Ernest V.; Horner,Glenn A.; Jakub,Cheryl A.; Kling,John E.; Nieglos,Donald J.; Schneider,Robert E.; Smith,Robert J., Automated process for detecting the presence of a target nucleic acid in a sample.
Lair, Gary D.; Nguyen, Thanh N.; Li, Haitao; Li, Florence; Knight, Byron J.; Heinz, Robert E.; Macioszek, Jerzy A.; Davis, Christopher B.; Scalese, Robert F., Continuous process for performing multiple nucleic acid amplification assays.
Handique, Kalyan; Brahmasandra, Sundaresh N.; Ganesan, Karthik; Wu, Betty; Phadke, Nikhil; Parunak, Gene; Williams, Jeff, Integrated system for processing microfluidic samples, and method of using the same.
Ammann, Kelly G.; Schneider, Robert E.; Smith, Robert J., Method for agitating the contents of a reaction receptacle within a temperature-controlled environment.
Macioszek, Jerzy A.; Davis, Christopher B.; Lair, Gary D.; Nguyen, Thanh N.; Li, Haitao; Li, Florence F.; Knight, Byron J.; Scalese, Robert F.; Heinz, Robert E., Method for continuous mode processing of the contents of multiple reaction receptacles in a real-time amplification assay.
Ammann, Kelly G.; Burns, Ralph E.; Hansberry, Ernest V.; Horner, Glenn A.; Jakub, Cheryl A.; Kling, John E.; Nieglos, Donald J.; Schneider, Robert E.; Smith, Robert J., Method for detecting the presence of a nucleic acid in a sample.
Ammann, Kelly G.; Burns, Ralph E.; Hansberry, Ernest V.; Horner, Glenn A.; Jakub, Cheryl A.; Kling, John E.; Nieglos, Donald J.; Schneider, Robert E.; Smith, Robert J., Method for detecting the presence of a nucleic acid in a sample.
Ammann, Kelly G.; Burns, Ralph E.; Hansberry, Ernest V.; Horner, Glenn A.; Jakub, Cheryl A.; Kling, John E.; Nieglos, Donald J.; Schneider, Robert E.; Smith, Robert J., Method for detecting the presence of a nucleic acid in a sample.
Ammann, Kelly G.; Burns, Ralph E.; Hansberry, Ernest V.; Horner, Glenn A.; Jakub, Cheryl A.; Kling, John E.; Nieglos, Donald J.; Schneider, Robert E.; Smith, Robert J., Method for detecting the presence of a nucleic acid in a sample.
Ammann, Kelly G.; Schneider, Robert E.; Smith, Robert J., Method for introducing a fluid into a reaction receptacle contained within a temperature-controlled environment.
Ammann, Kelly G.; Burns, Ralph E.; Hansberry, Ernest V.; Horner, Glenn A.; Jakub, Cheryl A.; Kling, John E.; Nieglos, Donald J.; Schneider, Robert E.; Smith, Robert J., Method for performing an assay with a nucleic acid present in a specimen.
Macioszek, Jerzy A.; Davis, Christopher B.; Lair, Gary D.; Nguyen, Thanh N.; Li, Haitao; Li, Florence F.; Knight, Byron J.; Scalese, Robert F.; Heinz, Robert E., Method for performing multi-formatted assays.
Ammann, Kelly G.; Burns, Ralph E.; Hansberry, Ernest V.; Horner, Glenn A.; Jakub, Cheryl A.; Kling, John E.; Nieglos, Donald J.; Schneider, Robert E.; Smith, Robert J., Method for simultaneously performing multiple amplification reactions.
Knight, Byron J.; Opalsky, David; Schroeter, Brian, Method, system and apparatus for incorporating capacitive proximity sensing in an automated fluid transfer procedure.
Lundquist, Paul; Zaccarin, Denis; Lacroix, Yves; Maxham, Mark; Foquet, Mathieu; Turner, Stephen, Methods and systems for simultaneous real-time monitoring of optical signals from multiple sources.
Lundquist, Paul; Zaccarin, Denis; Lacroix, Yves; Maxham, Mark; Foquet, Mathieu; Turner, Stephen, Methods and systems for simultaneous real-time monitoring of optical signals from multiple sources.
Lundquist, Paul; Zaccarin, Denis; Lacroix, Yves; Turner, Stephen; Dixon, John, Methods and systems for simultaneous real-time monitoring of optical signals from multiple sources.
Handique, Kalyan; Brahmasandra, Sundaresh N.; Ganesan, Karthik; Williams, Jeff, Microfluidic system for amplifying and detecting polynucleotides in parallel.
Handique, Kalyan; Brahmasandra, Sundaresh N; Ganesan, Karthik; Williams, Jeff, Microfluidic system for amplifying and detecting polynucleotides in parallel.
Bedingham, William; Ludowise, Peter D.; Robole, Barry W., Multiplex fluorescence detection device having fiber bundle coupling multiple optical modules to a common detector.
Wilson, Brian D.; Davis, Matthew S.; Erickson, Matthew D.; Johnson, Alan N.; Maurer, Garrick A.; Schmidt, Daniel R.; Wiltsie, Joshua D., Reaction vessel.
Gubatayao, Thomas Catalino; Handique, Kalyan; Ganesan, Karthik; Drummond, Daniel M., Scanning real-time microfluidic thermocycler and methods for synchronized thermocycling and scanning optical detection.
Lair, Gary D.; Nguyen, Thanh N.; Li, Haitao; Li, Florence F.; Knight, Byron J.; Heinz, Robert E.; Macioszek, Jerzy A.; Davis, Christopher B.; Scalese, Robert F., Signal measuring system having a movable signal measuring device.
Wilson, Brian D.; Anderson, David L.; Erickson, Matthew D.; Johnson, Alan N.; Rosen, Michael J.; Schmidt, Daniel R.; Wiltsie, Joshua D., System and method including analytical units.
Wilson, Brian D.; Anderson, David L.; Davis, Matthew S.; Erickson, Matthew D.; Johnson, Alan N.; Maurer, Garrick A.; Rosen, Michael J.; Sauerburger, Mark F.; Schmidt, Daniel R.; Wiltsie, Joshua D., System and method including multiple processing lanes executing processing protocols.
Wilson, Brian D.; Alaruri, Sami D.; Davis, Matthew S.; Erickson, Matthew D.; Johnson, Alan N.; Maurer, Garrick A.; Sauerburger, Mark F.; Schmidt, Daniel R.; Wiltsie, Joshua D.; Stachelek, Thomas M.; Yang, David L., System and method including thermal cycler modules.
Lair, Gary D.; Nguyen, Thanh N.; Li, Haitao; Li, Florence F.; Knight, Byron J.; Heinz, Robert E.; Macioszek, Jerzy A.; Davis, Christopher B.; Scalese, Robert F., System for performing multi-formatted assays.
Heinz, Robert E.; Newell, Dennis; Opalsky, David; Rhubottom, Jason, Systems and methods for distinguishing optical signals of different modulation frequencies in an optical signal detector.
Heinz, Robert E.; Newell, Dennis; Opalsky, David; Rhubottom, Jason, Systems and methods for distinguishing optical signals of different modulation frequencies in an optical signal detector.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.