Spectral calibration method and system for multiple instruments
Abstract
Implementations of the present invention describe an apparatus for generating calibration factors for a spectral detector instrument. The calibration factors are derived from a calibration plate containing one or more spectral species in each well of the calibration plate. Each well is then exposed to an excitation source that causes the one or more spectral species in each of the wells to fluoresce. The signal response is measured and associated with each spectral species at each different well position in the calibration plate. Next, the measured signal response from each spectral species at each well position in the calibration plate is compared with a predetermined signal response for each spectral species. The results of this comparison can be used to determine a calibration factor for each well and spectral species to compensate for the difference between the measured signal response and the predetermined signal response.
Claims
exact text as granted — not AI-modified1 . A computer implemented method of generating calibration factors for a spectral detector instrument, comprising:
receiving a calibration plate comprising a plurality of wells, each at a different well position and each containing a spectrally distinguishable species; exposing the calibration plate to an excitation source to cause the spectrally distinguishable species in each of the wells to fluoresce; measuring a signal response associated with each spectral species at each different well position in the calibration plate; comparing the measured signal response for each spectral species at each well position in the calibration plate with a predetermined signal response for each spectral species; and determining a respective calibration factor for each spectral species in response to the comparison to compensate for the difference between the respective measured signal response and the predetermined signal response for each spectral species, wherein, wherein the calibration factors generated for each well compensate for variations in spectral responses due to many different angles of entry of the light into the different wells of the plurality of wells.
2 . The method of claim 1 further comprising: reusing the same calibration plate to generate a calibration factor for each well and spectral species for one or more different instruments in a single platform.
3 . The method of claim 1 further comprising: reusing the same calibration plate to generate a calibration factor for each well and spectral species for one or more different instruments from more than one different platforms.
4 . The method of claim 1 further comprising: reusing the same calibration plate to generate a calibration factor for each well and spectral species for one instrument over time.
5 . The method of claim 1 , wherein the calibration plate is selected from a set of plates including a 96-well plate, a 384-well plate and a plate having a multiple of 96-wells.
6 . The method of claim 1 , wherein the spectral species includes one or more dyes selected from a set including: FAM, SYBR Green, VIC, JOE, TAMRA, NED, CY-3, Texas Red, CY-5, Hex and ROX.
7 . The method of claim 3 wherein one dye is used as a passive reference to normalize the spectral species in each well of the calibration plate.
8 . The method of claim 1 wherein the predetermined concentration of one or more probes includes a passive reference and the concentration of each probe is also determined with respect to the passive reference.
9 . The method of claim 1 wherein the excitation source is selected from a set of excitation sources including: a laser device, Halogen Lamp, arc lamp, Organic LED and an LED device.
10 . The method of claim 1 wherein the measuring the signal response further comprises: performing a multicomponent analysis on the signal response to identify the contribution from each spectral species to the signal; and deconvolving the contribution from the spectral species associated with an excitation filter filtering the signal response.
11 . The method of claim 1 wherein the measuring signal response further comprises: using the signal response directly as a measure of the spectral species that corresponds to an excitation filter filtering the signal response.
12 - 16 . (canceled)
17 . The method of claim 16 wherein ROX is used as a passive reference.
18 . An apparatus for generating position-specific calibration factors for a spectral detector instrument, comprising:
means for receiving a calibration plate comprising a plurality of wells, each at a different respective well position, and containing a plurality of spectrally distinguishable species in each of the plurality of wells; an excitation source configured to expose calibration plate to light to cause the plurality of spectrally distinguishable species in each of the plurality of wells to fluoresce; a detector configured to measure a respective signal response associated with each spectrally distinguishable species at each respective well position of the calibration plate; a processor configured to: compare the respective measured signal response for each spectrally distinguishable species at each respective position of the plurality of wells in the calibration plate with a predetermined signal response for each spectrally distinguishable species; and determine a respective calibration factor for each well and each spectrally distinguishable species in response to the comparison to compensate for respective differences between the respective measured signal response and the predetermined signal response, wherein the calibration factors generated for each well compensate for variations in spectral responses due to many different angles of entry of the light into the different wells of the plurality.
19 . A non-transitory computer-readable medium comprising instructions, executable by a processor, the instructions comprising instructions for:
receiving a plate comprising a plurality of wells, each well of the plate having a different respective well position and containing one or more potential targets and a plurality of spectrally distinguishable species; exposing each well in the plate to an excitation source that emits light and causes the spectrally distinguishable species to fluoresce in correlation to the presence of one or more of the one or more potential targets; measuring the respective initial signal values received from each of the spectrally distinguishable species in each of the respective well positions of the plate; and adjusting the respective initially measured signal values using a respective calibration factor for each well position and each different spectrally distinguishable species from a calibration plate having predetermined relative concentrations of the one or more spectrally distinguishable species, wherein the respective calibration factors compensate for respective differentials between a respective measured signal response in the calibration plate compared with a predetermined signal response for each of the spectrally distinguishable species.Cited by (0)
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