System, method, and product for dynamic noise reduction in scanning of biological materials

Description

BACKGROUND OF INVENTION

1. Field of the Invention

The present invention relates to scanning systems for examining biological material and, in particular, to noise reduction in optical scanning systems having a laser to excite fluorescently tagged biological materials.

2. Related Art

Synthesized nucleic acid probe arrays, such as Affymetrix® GeneChip® synthesized probe arrays, have been used to generate unprecedented amounts of information about biological systems. For example, a commercially available GeneChip® array set from Affymetrix, Inc. of Santa Clara, Calif., is capable of monitoring the expression levels of approximately 6,500 murine genes and expressed sequence tags (EST's). Experimenters can quickly design follow-on experiments with respect to genes, EST's, or other biological materials of interest by, for example, producing in their own laboratories microscope slides containing dense arrays of probes using the Affymetrix® 417™ or 427™ Arrayers or other spotting devices. Analysis of data from experiments with synthesized and/or spotted probe arrays may lead to the development of new drugs and new diagnostic tools.

In some conventional applications, this analysis begins with the capture of fluorescent signals indicating hybridization of labeled target samples with probes on synthesized or spotted probe arrays. The devices used to capture these signals often are referred to as scanners. Due to the relatively small emission signals sometimes available from the hybridized target-probe pairs, the presence of background fluorescent signals, the high density of the arrays, variations in the responsiveness of various fluorescent labels, and other factors, care must be taken in designing scanners to properly acquire and process the fluorescent signals indicating hybridization. For example, U.S. Pat. No. 6,171,793 to Phillips, et al., hereby incorporated herein in its entirety for all purposes, describes a method for scanning probe arrays to provide data having a dynamic range that exceeds that of the scanner. Nonetheless, there is a continuing need to improve scanner design to provide more accurate and reliable fluorescent signals and thus provide experimenters with more sensitive and accurate data.

SUMMARY OF INVENTION

Systems, methods, and products to address these and other needs are described herein with respect to illustrative, non-limiting, implementations. Various alternatives, modifications and equivalents are possible. For example, certain systems, methods, and computer software products are described herein using exemplary implementations for analyzing data from arrays of biological materials produced by the Affymetrix® 417™ or 427™ Arrayer. Other illustrative implementations are referred to in relation to data from Affymetrix® GeneChip® probe arrays. However, these systems, methods, and products may be applied with respect to many other types of probe arrays and, more generally, with respect to numerous parallel biological assays produced in accordance with other conventional technologies and/or produced in accordance with techniques that may be developed in the future. For example, the systems, methods, and products described herein may be applied to parallel assays of nucleic acids, PCR products generated from cDNA clones, proteins, antibodies, or many other biological materials. These materials may be disposed on slides (as typically used for spotted arrays), on substrates employed for GeneChip® arrays, or on beads, optical fibers, or other substrates or media. Moreover, the probes need not be immobilized in or on a substrate, and, if immobilized, need not be disposed in regular patterns or arrays. For convenience, the term probe array will generally be used broadly hereafter to refer to all of these types of arrays and parallel biological assays.

In accordance with one preferred embodiment, a method is described that includes the steps of (1) directing an excitation beam to a plurality of pixel locations on a substrate; (2) determining one or more representative excitation values, each related to a value of the excitation beam as directed to at least one of the plurality of pixel locations; (3) detecting an emission signal having one or more emission values; (4) correlating each of the one or more emission values with one or more of the representative excitation values; (5) providing at least one excitation reference value; (6) comparing the excitation reference value to at least one representative excitation value, thereby generating a normalization factor; and (7) adjusting at least one emission value based, at least in part, on the normalization factor. One or more probes of a biological microarray may be disposed in relation to the substrate; for example, probes may be coupled to the substrate. The one or more probes may be disposed at different probe locations on a surface of the substrate. In some implementations, the substrate may include different polymer sequences coupled to the surface of the substrate. The different polymer sequences may include different oligonucleotide sequences, wherein each of the different polymer sequences is coupled in a different probe location of the surface. In some implementations, each of the probe locations has an area of one-hundredth of a square centimeter or less. Also, in some implementations, the substrate may include more than one thousand different ligands of known sequence collectively occupying an area of less than one square centimeter, the different ligands occupying different known locations within the area.

In accordance with further implementations of these preferred embodiments, step (2) includes directing the excitation beam to a dichroic mirror, and determining the representative excitation values based on a partial excitation beam that passes through the dichroic mirror. Also, the emission signal may arise from the direction of the excitation beam to the plurality of pixel locations. As used in this context, the word arise is intended to have a broad meaning so as to encompass various cause and effect relationships wherein the directing of the excitation beam causes or results in, directly or indirectly, the emission signal. As just one non-limiting example, the excitation beam may be a laser beam directed to a location on the substrate where fluorescently labeled receptors are disposed, and the emission signal may be a fluorescent signal resulting from excitation of those labeled receptors. In these and other implementations, step (4) may include spatially correlating the emission values with the representative excitation values. Also in these and other implementations, step (2) may include determining a first representative excitation value related to a power of the excitation beam as directed to a first of the plurality of pixel locations; step (3) may include detecting an emission value arising from the direction of the excitation beam to the first pixel location; and step (4) may include correlating the first emission value with the first representative excitation value. In accordance with various embodiments, the excitation reference value may be based, at least in part, on at least one of the one or more representative excitation values, and/or on a plurality of representative excitation values related to values of the excitation beam as directed to pixel locations in one or more scan lines.

The method, in accordance with some embodiments, may further include the step of (8) filtering the representative excitation values to provide one or more filtered representative excitation values. In these embodiments, the excitation reference value is based, at least in part, on at least one of the one or more filtered representative excitation values. In these and other embodiments, the excitation reference value may be based, at least in part, on a measured calibration value and/or on a predetermined specification value.

In accordance with yet other embodiments, a system is described for processing an emission signal having one or more emission values. The system includes an excitation signal generator that provides an excitation signal having one or more representative excitation values representative of an excitation beam. The system also has an excitation reference provider that provides at least one excitation reference value; a normalization factor generator that compares the excitation reference value to at least one representative excitation value, thereby generating a normalization factor; and a comparison processor that adjusts at least one emission value corresponding to the at least one representative excitation value based, at least in part, on the normalization factor. The excitation reference value may be determined based at least in part on a low-frequency component of the excitation signal. The at least one representative excitation value may include, as examples, an instantaneous analog value or a sampled digital value. In some implementations, the comparison processor adjusts the at least one emission value corresponding to the at least one representative excitation value based on multiplying or dividing the emission value by the normalization factor. The excitation signal may include a laser signal, and the emission signal may include a fluorescent signal resulting from excitation of a fluorophore by the laser signal.

In accordance with a further embodiment, a method is described for processing an emission signal having one or more emission values. The method includes providing at least one excitation reference value; comparing the excitation reference value to at least one excitation value, thereby generating a normalization factor; and adjusting at least one emission value corresponding to the at least one excitation value based, at least in part, on the normalization factor.

A scanning system is described in accordance with some embodiments. The system includes one or more excitation sources that generate one or more excitation beams; an excitation signal generator that provides an excitation signal having one or more representative excitation values representative of the excitation beam; an excitation reference provider that provides at least one excitation reference value; a normalization factor generator that compares the excitation reference value to at least one representative excitation value, thereby generating a normalization factor; and a comparison processor that adjusts at least one emission value corresponding to the at least one representative excitation value based, at least in part, on the normalization factor. The scanning system may include a processor and a memory unit, wherein the normalization factor generator includes a set of normalization factor generating instructions stored in the memory unit and executed in cooperation with the processor. The comparison processor may also include a set of comparison processing instructions stored in the memory unit and executed in cooperation with the processor.

A computer program product is described with respect to other embodiments. The product includes a set of normalization factor generating instructions stored in a memory unit of a computer and executed in cooperation with a processor of the computer. These instructions are constructed and arranged to compare at least one excitation reference value to at least one representative excitation value, thereby generating a normalization factor. The product also includes a set of comparison processing instructions stored in the memory unit and executed in cooperation with the processor, constructed and arranged to adjust at least one emission value corresponding to the at least one representative excitation value based, at least in part, on the normalization factor. The at least one emission value results from excitation of a labeled receptor at a probe location of a probe array.

A method for analyzing molecules is described with respect to some embodiments. The method includes (1) directing an excitation beam to a plurality of pixel locations on a surface having a plurality of probe locations, each probe location including one or more probe molecules; (2) determining one or more representative excitation values, each related to a value of the excitation beam as directed to at least one of the plurality of pixel locations; (3) detecting an emission signal having one or more emission values; (4) correlating each of the one or more emission values with one or more of the representative excitation values; (5) providing at least one excitation reference value; (6) comparing the excitation reference value to at least one representative excitation value, thereby generating a normalization factor; (7) adjusting at least one emission value based, at least in part, on the normalization factor; and (8) analyzing at least one probe location based, at least in part, on the at least one adjusted emission value.

The above embodiments and implementations are not necessarily inclusive or exclusive of each other and may be combined in any manner that is non-conflicting and otherwise possible, whether they be presented in association with a same, or a different, embodiment or implementation. The description of one embodiment or implementation is not intended to be limiting with respect to other embodiments and/or implementations. Also, any one or more function, step, operation, or technique described elsewhere in this specification may, in alternative implementations, be combined with any one or more function, step, operation, or technique described in the summary. Thus, the above embodiment and implementations are illustrative rather than limiting.

BRIEF DESCRIPTION OF DRAWINGS

The above and further features will be more clearly appreciated from the following detailed description when taken in conjunction with the accompanying drawings. In the drawings, like reference numerals indicate like structures or method steps and the leftmost digit of a reference numeral indicates the number of the figure in which the referenced element first appears (for example, the element

160

appears first in FIG.

1

). In functional block diagrams, rectangles generally indicate functional elements and parallelograms generally indicate data. In method flow charts, rectangles generally indicate method steps and diamond shapes generally indicate decision elements. All of these conventions, however, are intended to be typical or illustrative, rather than limiting.

FIG. 1

is a simplified graphical representation of an arrangement of scanner optics and detectors suitable for providing excitation and emission signals for processing by a noise compensation module such as shown in

FIG. 4

or

9

.

FIG. 2A

is a perspective view of a simplified exemplary configuration of a scanning arm portion of the scanner optics and detectors of FIG.

1

.

FIG. 2B

is a top planar view of the scanning arm of

FIG. 2A

as it scans biological features on one embodiment of a probe array being moved by a translation stage under the arm's arcuate path.

FIG. 3

is a functional block diagram of one embodiment of a scanner-computer system including a scanner having a noise compensation module such as shown in

FIG. 4

or

9

.

FIG. 4

is a functional block diagram of one embodiment of a noise compensation module for providing an emission signal normalized to compensate for noise in the excitation source.

FIG. 5A

is a graphical representation of one embodiment of a probe feature showing bi-directional scanning lines such as may be implemented using the scanning arm of

FIGS. 2A and 2B

.

FIG. 5B

is an illustrative plot of pixel clock pulses aligned with the scanned probe feature of

FIG. 5A

to show illustrative radial position sampling points.

FIG. 5C

is an illustrative plot of sampled emission voltages aligned with the pixel clock pulses of FIG.

5

B.

FIG. 5D

is an illustrative plot of sampled excitation voltages aligned with the pixel clock pulses of FIG.

5

B.

FIG. 6A

is a graphical representation of a simulated input waveform including noise.

FIGS. 6B and 6C

are graphical representations of output waveforms from alternative embodiments of asymmetrical filters responsive to the input waveform of FIG.

6

A.

FIGS. 6D and 6E

are graphical representations of output waveforms from alternative embodiments of symmetrical filters responsive to the input waveform of FIG.

6

A.

FIG. 7A

is a graphical representation of an input waveform plotted as a function of pixel clock pulses.

FIG. 7B

is a graphical representation of an output waveform from one embodiment of an asymmetrical filter responsive to the input waveform of

FIG. 7A

as a function of pixel clock pulses in a sequence determined by scanning in a first direction.

FIG. 7C

is a graphical representation of an output waveform from the asymmetrical filter of

FIG. 7B

responsive to the input waveform of

FIG. 7A

as a function of pixel clock pulses in a sequence determined by scanning in a second direction opposite to the first direction.

FIG. 7D

is a consolidated graphical representation of pixels shown in

FIGS. 7B and 7C

resulting from successive bi-directional scans of a probe feature under asymmetrical filtering.

FIG. 7E

is a graphical representation of the pixels of

FIG. 7D

shifted so as to graphically compensate for the effects of phase delay.

FIG. 8A

is a graphical representation of an input waveform plotted as a function of pixel clock pulses.

FIG. 8B

is a graphical representation of an output waveform from one embodiment of a symmetrical filter responsive to the input waveform of

FIG. 8A

as a function of pixel clock pulses in a sequence determined by scanning in a first direction.

FIG. 8C

is a graphical representation of an output waveform from the symmetrical filter of

FIG. 8B

responsive to the input waveform of

FIG. 8A

as a function of pixel clock pulses in a sequence determined by scanning in a second direction opposite to the first direction.

FIG. 8D

is a consolidated graphical representation of pixels shown in

FIGS. 8B and 8C

resulting from successive bi-directional scans of a probe feature under symmetrical filtering.

FIG. 8E

is a graphical representation of the pixels of

FIG. 8D

shifted so as to graphically compensate for the effects of phase delay.

FIG. 9

is a functional block diagram of one embodiment of a noise compensation module for providing, together with a digital signal processing board and software on an associated computer, emission data normalized to compensate for noise in the excitation source.

FIG. 10

is a functional block diagram of one embodiment of aspects of a computer of the scanner-computer system of

FIG. 3

suitable for generating normalized emission signal data.

DETAILED DESCRIPTION

The description below is designed to present preferred embodiments and not to be construed as limiting in any way. Also, reference will be made to articles and patents to show general features that are incorporated into the present disclosure. Many scanner designs may be used in order to provide excitation and emission appropriate for processing by noise compensation module

310

, which is described in detail below. In reference to the illustrative implementation of

FIG. 1

, the term excitation beam refers to light beams generated by lasers. However, excitation sources other than lasers may be used in alternative implementations. Thus, the term excitation beam is used broadly herein. The term emission beam also is used broadly herein. A variety of conventional scanners detect fluorescent or other emissions from labeled target molecules or other material associated with biological probes. Other conventional scanners detect transmitted, reflected, or scattered radiation from such targets. These processes are sometimes generally and collectively referred to hereafter for convenience simply as involving the detection of emission beams. Various detection schemes are employed depending on the type of emissions and other factors. A typical scheme employs optical and other elements to provide an excitation beam, such as from a laser, and to selectively collect the emission beams. Also generally included are various light-detector systems employing photodiodes, charge-coupled devices, photomultiplier tubes, or similar devices to register the collected emission beams. For example, a scanning system for use with a fluorescently labeled target is described in U.S. Pat. Nos. 5,143,854 and 6,225,625, hereby incorporated by reference in their entireties for all purposes. Other scanners or scanning systems are described in U.S. Pat. Nos. 5,578,832; 5,631,734; 5,834,758; 5,936,324; 5,981,956; 6,025,601; 6,141,096; 6,185,030; 6,201,639; and 6,218,803 and in PCT Application PCT/US99/06097 (published as WO99/47964), each of which also is hereby incorporated by reference in its entirety for all purposes.

Scanner Optics and Detectors

100

.

FIG. 1

is a simplified graphical representation of illustrative scanner optics and detectors (hereafter, simply scanner optics)

100

. Scanner optics

100

includes excitation sources

120

A and

120

B (generally and collectively referred to as excitation sources

120

). Any number of one or more excitation sources

120

may be used in alternative embodiments. In the present example, sources

120

are lasers; in particular, source

120

A is a diode laser producing red laser light having a wavelength of 635 nanometers and, source

120

B is a doubled YAG laser producing green laser light having a wavelength of 532 nanometers. Further references herein to sources

120

generally will assume for illustrative purposes that they are lasers, but, as noted, other types of sources, e.g., x-ray sources, may be used in other implementations.

In the illustrated implementation, it is assumed that only one of excitation sources

120

A and

120

B is operational (in the sense of generating an excitation beam

135

) at any particular time. For example, source

120

A and not source

120

B may be operational for one arc scan by scanner optics

100

, as described below, and source

120

B and not source

120

A may be operational for a subsequent scan. Sources

120

A and

120

B may alternate between successive scans, groups of successive scans, or between full scans of an array. For clarity, excitation beams

135

A and

135

B are shown as distinct from each other in FIG.

1

. However, in practice, turning mirror

124

and/or other optical elements (not shown) typically are adjusted to provide that these beams follow the same path. Moreover, it also will be understood that the assumption that only one laser is operational at a time is made only for the sake of convenience and clarity of illustration. Implementations are contemplated that include simultaneous operation of any number of excitation sources

120

. Beams

135

in simultaneous operation typically, but need not, follow the same path. Handbook of Biological Confocal Microscopy (James B. Pawley, ed.) (2.ed.; 1995; Plenum Press, NY), which includes information known to those of ordinary skill in the art regarding the use of lasers and associated optics, is hereby incorporated herein by reference in its entirety.

Scanner optics

100

also includes excitation filters

125

A and

125

B that optically filter beams from excitation sources

120

A and

120

B, respectively. Filters

125

optionally are used to remove light at wavelengths other than the desired wavelengths, and need not be included if, for example, sources

120

A and

120

B do not produce light at these extraneous wavelengths. As noted, however, it may be desirable in some applications to use inexpensive lasers and often it is cheaper to filter out-of-mode laser emissions than to design the laser to avoid producing such extraneous emissions.

The filtered excitation beams from sources

120

A and

120

B are combined in accordance with any of a variety of known techniques. For example, one or more mirrors, such as turning mirror

124

, may be used to direct filtered beam from source

120

A through beam combiner

130

. The filtered beam from source

120

B is directed at an angle incident upon beam combiner

130

such that the beams combine in accordance with optical properties techniques well known to those of ordinary skill in the relevant art. Most of combined excitation beams

135

A and

135

B (generally and collectively referred to as beams

135

) are reflected by dichroic mirror

136

and thence directed to periscope mirror

138

of the illustrative example. However, dichroic mirror

136

has characteristics selected so that portions of beams

135

A and

135

B, referred to respectively as partial excitation beams

137

A and

137

B and generally and collectively as beams

137

, pass through it so that they may be detected by excitation detector

110

.

Detector

110

may be any of a variety of conventional devices for detecting partial excitation beams

137

, such as a silicon detector for providing an electrical signal representative of detected light, a photodiode, a charge-coupled device, a photomultiplier tube, or any other detection device for providing a signal indicative of detected light that is now available or that may be developed in the future. Detector

110

generates excitation signal

194

that represents detected partial excitation beams

137

A or

137

B. In accordance with known techniques, the amplitude, phase, or other characteristic of excitation signal

194

is designed to vary in a known or determinable fashion depending on the power of excitation beam

135

. The term power in this context refers to the capability of beam

135

to evoke emissions. For example, the power of beam

135

typically may be measured in milliwatts of laser energy with respect to the illustrated example in which the laser energy evokes a fluorescent signal. Thus, excitation signal

194

has values that represent the power of beam

135

during particular times or time periods.

In the illustrated example, excitation beams

135

are directed via periscope mirror

138

and arm end turning mirror

142

to an objective lens

145

. As described in greater detail below in relation to

FIGS. 2A and 2B

, lens

145

in the illustrated implementation is a small, light-weight lens located on the end of an arm that is driven by a galvanometer around an axis perpendicular to the plane represented by galvo rotation

149

shown in FIG.

1

. Objective lens

145

thus moves in arcs over a substrate upon which biological materials have been synthesized or have been deposited. Flourophores associated with these biological materials emit emission beam

152

(beam

152

A in response to excitation beam

135

A, and beam

152

B in response to excitation beam

135

B) at characteristic wavelengths in accordance with well known principles. Emission beam

152

in the illustrated example follows the reverse path as described with respect to excitation beam

135

until reaching dichroic mirror

136

. In accordance with well known techniques and principles, the characteristics of mirror

136

are selected so that beam

152

(or a portion of it) passes through the mirror rather than being reflected.

In the illustrated implementation, filter wheel

160

is provided to filter out spectral components of emission beam

152

that are outside of the emission band of the fluorophore. The emission band is determined by the characteristic emission frequencies of those fluorophores that are responsive to the frequency of excitation beam

135

. Thus, for example, excitation beam

135

A from source

120

A, which is illustratively assumed to have a wavelength of 635 nanometers, excites certain fluorophores to a much greater degree than others. The characteristic emission wavelength of a first illustrative fluorophore (not shown in

FIG. 1

) when excited by beam

135

A is assumed to be 665 nanometers. Emission beam

152

A in this example typically will also include wavelengths above and below 665 nanometers in accordance with distributions that are known to those of ordinary skill in the relevant art. Similarly, the characteristic emission wavelength of a second illustrative fluorophore (not shown in FIG.

1

), when excited by beam

135

A having a wavelength of 532 nanometers, is illustratively assumed to be 551 nanometers. Thus, when excitation source

120

A is operational, filter wheel

160

is turned so that filter

162

A is selected (typically under computer control) and wavelengths other than 665 nanometers are removed from filtered emission beam

154

. Similarly, filter

162

B is selected when source

120

B is operational so that wavelengths other than 551 nanometers are filtered out of beam

152

B to produce filtered emission beam

154

. In accordance with techniques well known to those of ordinary skill in the relevant arts, including that of confocal microscopy, beam

154

may be focused by various optical elements such as lens

165

and also passed through illustrative pinhole

167

or other element to limit the depth of field, and thence impinges upon emission detector

115

.

Similar to excitation detector

110

, emission detector

115

may be a silicon detector for providing an electrical signal representative of detected light, or it may be a photodiode, a charge-coupled device, a photomultiplier tube, or any other detection device that is now available or that may be developed in the future for providing a signal indicative of detected light. Detector

115

generates emission signal

192

that represents filtered emission beam

154

in the manner noted above with respect to the generation of excitation signal

194

by detector

110

. Emission signal

192

and excitation signal

194

are provided to noise compensation module

310

for processing, as described below in relation to

FIGS. 3 and 4

.

FIG. 2A

is a perspective view of a simplified representation of an illustrative scanning arm portion of scanner optics

100

in accordance with this particular, non-limiting, implementation. Arm

200

moves in arcs around axis

210

, which is perpendicular to the plane of galvo rotation

149

. A position transducer

215

is associated with galvanometer

215

that, in the illustrated implementation, moves arm

200

in bi-directional arcs. Transducer

215

, in accordance with any of a variety of known techniques, provides an electrical signal indicative of the radial position of arm

200

. Certain non-limiting implementations of position transducers for galvanometer-driven scanners are described in U.S. Pat. No. 6,218,803 to Montagu, et al., which is hereby incorporated by reference in its entirety for all purposes. As described below, the signal from transducer

215

is provided in the illustrated implementation to computer

350

so that clock pulses may be provided for digital sampling of emission signals when arm

200

is in certain positions along its scanning arc.

Arm

200

is shown in alternative positions

200

′ and

200

″ as it moves back and forth in scanning arcs about axis

210

. Excitation beams

135

pass through objective lens

145

on the end of arm

200

and excite fluorophores that may be contained in hybridized probe-target pairs in features

230

on a substrate of probe array

240

, as further described below. The arcuate path of excitation beams

135

over probe array

240

is schematically shown for illustrative purposes as path

250

. Emission beams

152

pass up through objective lens

145

as noted above. Probe array

240

of this example is disposed on translation stage

242

that is moved in direction

244

so that arcuate path

250

repeatedly crosses the plane of probe array

240

. As is evident, the resulting coverage of excitation beams

135

over the plane of probe array

240

is therefore determined by the footprint of beam, the speed of movement in direction

244

, and the speed of the scan.

FIG. 2B

is a top planar view of arm

200

with objective lens

145

scanning features

230

on probe array

240

as translation stage

242

is moved under path

250

. As shown in

FIG. 2B

, arcuate path

250

of this example is such that arm

200

has a radial displacement of θ in each direction from an axis parallel to direction

244

. For convenience of reference below, a direction

243

perpendicular to direction

244

is also shown in FIG.

2

B. For illustrative purposes, direction

243

may hereafter be referred to as the x direction, and direction

244

as the y direction.

Further details of confocal, galvanometer-driven, arcuate, laser scanning instruments suitable for detecting fluorescent emissions are provided in PCT Application PCT/US99/06097 (published as WO99/47964) and in U.S. Pat. Nos. 6,185,030; 6,201,639; and 6,225,625, all of which have been incorporated by reference above.

Probe Array

240

.

Probe array

240

as shown in

FIGS. 2A and 2B

is illustrative only and it will be understood that numerous variations are possible with respect to providing biological materials for scanning. For example, Affymetrix® GeneChip® arrays commercially available from Affymetrix, Inc., of Santa Clara, Calif., referred to above, are synthesized in accordance with techniques sometimes referred to as VLSIPS™ (Very Large Scale Immobilized Polymer Synthesis) technologies. Probe arrays developed with these technologies, and others that are now available and may in the future be developed for synthesizing arrays of biological materials, may hereafter be referred to for convenience as synthesized probe arrays. This term refers generally to arrays in which probes have been built in situ on an array substrate, as contrasted, for to arrays in which pre-synthesized or pre-selected probes are deposited or positioned on or within a substrate.

Some aspects of VLSIPS™ technologies are described in the following U.S. Pat. No. 5,143,854 to Pirrung, et al.; U.S. Pat. No. 5,445,934 to Fodor, et al.; U.S. Pat. No. 5,744,305 to Fodor, et al.; U.S. Pat. No. 5,831,070 to Pease, et al.; U.S. Pat. No. 5,837,832 to Chee, et al.; U.S. Pat. No. 6,022,963 to McGall, et al.; and U.S. Pat. No. 6,083,697 to Beecher, et al. Each of these patents is hereby incorporated by reference in its entirety. The probes of these arrays typically consist of oligonucleotides that typically are synthesized by methods that include the steps of activating regions of a substrate and then contacting the substrate with a selected monomer solution. The regions are activated with a light source shown through a mask in a manner similar to photolithographic techniques used in the fabrication of integrated circuits. Other regions of the substrate remain inactive because the mask blocks them from illumination. By repeatedly activating different sets of regions and contacting different monomer solutions with the substrate, a diverse array of polymers is produced on the substrate. A variety of other techniques also exist for synthesizing probe arrays. For example, U.S. Pat. Nos. 5,885,837 and 6,040,193 describe the use of micro-channels or micro-grooves on a substrate, or on a block placed on a substrate, to synthesize arrays of biological materials.

As noted, techniques also exist for depositing or positioning pre-synthesized or pre-selected probes on or within a substrate or support. For convenience, probe arrays made in accordance with these other techniques, or depositing/positioning techniques that may be developed in the future, may hereafter be referred to as spotted arrays. Typically, spotted arrays are commercially fabricated on microscope slides. These arrays typically consist of liquid spots containing biological material of potentially varying compositions and concentrations. For instance, a spot in the array may include a few strands of short polymers, such as oligonucleotides in a water solution, or it may include a high concentration of long strands of polymers, such as complex proteins. The Affymetrix® 417™ and 427™ Arrayers are devices that deposit densely packed probe arrays of biological material on a microscope slide in accordance with these techniques. Aspects of these, and other, spot arrayers are described in U.S. Pat. Nos. 6,121,048 and 6,136,269, in PCT Applications Nos. PCT/US99/00730 (International Publication Number WO99/36760) and PCT/US 01/04285, in U.S. patent application Ser. Nos. 09/122,216, 09/501,099, and 09/862,177, and in U.S. Provisional Patent Application Serial No. 60/288,403, all of which are hereby incorporated by reference in their entireties for all purposes. Other techniques for generating spotted arrays also exist. For example, U.S. Pat. No. 6,040,193 to Winkler, et al., is directed to processes for dispensing drops to generate spotted arrays. The '193 patent, and U.S. Pat. No. 5,885,837 to Winkler, also describe separating reactive regions of a substrate from each other by inert regions and spotting on the reactive regions. The '193 and '837 patents are hereby incorporated by reference in their entireties. Other techniques are based on ejecting jets of biological material to form spotted arrays. Other implementations of the jetting technique may use devices such as syringes or piezo electric pumps to propel the biological material.

Synthesized or spotted probe arrays typically are used in conjunction with tagged biological samples such as cells, proteins, genes or EST's, other DNA sequences, or other biological elements. These samples, referred to herein as targets, are processed so that they are spatially associated with certain probes in the probe array. For example, one or more chemically tagged biological samples, i.e., the targets, are distributed over the probe array. Some targets hybridize with at least partially complementary probes and remain at the probe locations, while non-hybridized targets are washed away. These hybridized targets, with their tags or labels, are thus spatially associated with the targets' complementary probes. The hybridized probe and target may sometimes be referred to as a probe-target pair. Detection of these pairs by scanners can serve a variety of purposes, such as to determine whether a target nucleic acid has a nucleotide sequence identical to or different from a specific reference sequence. See, for example, U.S. Pat. No. 5,837,832, referred to and incorporated above. Other uses include gene expression monitoring and evaluation (see, e.g., U.S. Pat. No. 5,800,992 to Fodor, et al.; U.S. Pat. No. 6,040,138 to Lockhart, et al.; and International App. No. PCT/US98/15151, published as WO99/05323, to Balaban, et al.), genotyping (U.S. Pat. No. 5,856,092 to Dale, et al.), or other detection of nucleic acids. The '992, '138, and '092 patents, and publication WO99/05323, are incorporated by reference herein in their entirety for all purposes for the uses stated above and all the uses that are disclosed therein.

To ensure proper interpretation of the term probe as used herein, it is noted that contradictory conventions exist in the relevant literature. The word probe is used elsewhere in some contexts to refer not to the biological material that is synthesized on a substrate or deposited on a slide, as described above, but to what has been referred to herein as the target. To avoid confusion, the term probe is used herein to refer to probes such as those synthesized according to the VLSIPS™ technology; the biological materials deposited or positioned so as to create spotted arrays; and materials synthesized, deposited, or positioned to form arrays according to other current or future technologies. Moreover, as noted, the term probe is not limited to probes immobilized in array format. Rather, the functions and methods described herein may also be employed with respect to other parallel assay devices and techniques. Also, in some cases the sequence and/or composition of the probes may not be known, or may not be fully known.

Noise Compensation Module

310

.

FIG. 3

is a functional block diagram of a scanner-computer system showing scanner

300

under the control of computer

350

. A component of scanner

300

is noise compensation module

310

that, among other things, conditions emission signals

192

and excitation signals

194

to provide bi-directional edge and feature clarification. In the illustrated implementations, this function is accomplished using an excitation signal filter having appropriate smoothing characteristics and symmetrical rise and fall characteristics, and a matched emission signal filter. In some implementations, such as shown in

FIG. 4

, module

310

also includes a hardware-implemented normalization factor generator

450

. Generator

450

generates a normalization factor

452

that is provided to compensation processor

460

. Based on normalization factor

452

, processor

460

adjusts emission signals

192

for noise in excitation signals

194

. The resulting normalized emission signal

312

is shown in

FIG. 3

in dotted lines to emphasize that it is the product of an optional configuration. In some other embodiments, a software application executed on computer

350

, together with a digital signal processor board in the computer, implement the functions of generating a compensating factor and adjusting emission signals

192

to compensate for noise in excitation signals

194

. The result is normalized emission signal data

374

stored in system memory

370

of computer

350

for further processing and/or display. The functions of certain components of scanner

300

and computer

350

are interchangeable in some implementations. As a non-limiting example, some or all of the functions of digital signal processor board

380

, as well as those of scanner control and analysis applications executables

372

may, in some implementations, be carried out by noise compensation module

310

. The functions of module

310

are now further described, first in an example in which module

310

carries out both bi-directional edge clarification and noise compensation, and then in an example in which the latter function is carried out by software executing on computer

350

.

FIG. 4

is a functional block diagram of one implementation of noise compensation module

310

, referred to as module

310

A. Using primarily hardware components, illustrative module

310

A adjusts emission signal

192

to compensate for noise in excitation source

120

, thereby providing normalized emission signal

312

. Module

310

A includes a series of a number N gain generators

410

. Under the control of computer

350

, gain generators

410

provide adjustable gains so that excitation signal

194

is normalized irrespective of excitation source. This normalization is provided to compensate for differences in the amplitude of excitation signal

194

due to differences in optical parameters of scanner optics and detectors

100

at different wavelengths of excitation beam

135

. These optical parameters include the percentage of light of different wavelengths that passes through dichroic mirror

136

, optical losses due to mirror reflection that may vary according to wavelength, the response characteristics of excitation detector

110

as a function of wavelength, and other factors that will be appreciated by those of ordinary skill in the relevant art.

Gain generators

410

may be implemented in accordance with any of a variety of conventional techniques, or ones that may be developed in the future, for changing the amplitude of a signal. The gains provided by each of generators

410

may be predetermined based on calibration protocols; for example, variable resistors may be adjusted by a technician during manufacture so that a standard amount of power provided by each of excitation sources

120

results in a same voltage for gain-normalized excitation signal

422

. Alternatively, this adjustment function could be performed automatically by scanner control and analysis executables

372

. For example, under the control of executables

372

, each of excitation sources

120

may successively be enabled and a representative value of excitation signal

194

be calculated for each. In accordance with known techniques, these calculated values may be provided to generators

410

to change gain parameters to achieve signal normalization.

Module

310

A also includes multiplexer

420

that, under the control of computer

350

in this implementation, selects the normalized excitation signal provided by the gain generator corresponding to the one of excitation sources

120

that is operational. For example, during a period when computer

350

has made excitation source

120

A operational, and assuming for illustrative purposes that gain generator

410

A has been calibrated to source

120

A, then computer

350

provides an appropriate enabling or control signal to multiplexer

420

so that the signal from generator

410

A is selected. Multiplexer

420

may select from any number of N inputs to provide, in the illustrated implementation, one selected output, shown in

FIG. 4

as gain-normalized excitation signal

422

. Any of numerous conventional or future multiplexers or switches may be used to provide this function.

Another component of module

310

A in the illustrated implementation is gain generator

490

. Generator

490

adjusts the gain of emission signal

192

in accordance with known techniques to provide that the input to filter

440

is within a nominal range of amplitudes or, alternatively, has a nominal steady-state component. Thus, for example, if the emissions of a particular fluorophore in a particular assay occur over a relatively small dynamic range, the emission signal from that fluorophore may optionally be adjusted by gain generator

490

to provide a proportionately larger-range signal for filtering and subsequent sampling. The magnitude of the gain adjustment may, in some implementations, be user selected. For example, a user may employ a graphical user interface (not shown) or other input technique to specify to scanner control and analysis executables

372

what the gain provided by gain generator

490

should be. This determination typically is made based on the fluorophores used in a particular assay and a list of illustrative gains that may be presented to the user in a pull down menu of the graphical user interface or in accordance with any of a variety of other known techniques. In other implementations, the gain value may be determined automatically by scanner control and analysis executables

372

. For example, executables

372

may measure emission signal

192

to determine its low-frequency components, peak-to-peak amplitudes, or other indicators of dynamic range. In accordance with known techniques, executables

372

may then consult a look-up table included, for example, in calibration data

376

, to compare the measured indicators with nominal values, and adjusts the gain accordingly.

Also included in noise compensation module

310

A is emission filter

440

. Emission filter

440

performs an anti-aliasing function so that normalized emission signal

312

may be digitized without aliasing errors. In the illustrated implementation, filter

440

is a low-pass filter. As noted, it is not uncommon for high-frequency noise to be present in the outputs of less expensive lasers, and the magnitude of this noise may constitute a substantial portion (e.g., 60%) of the magnitude of the signal. Generally, emissions of fluorophores are linearly related to their excitation throughout a range of interest in typical scanner applications. Therefore, high frequency noise from the lasers in excitation beam

135

produces high frequency noise of the same character in emission signal

192

and adjusted emission signal

462

and, of course, in excitation signal

194

.

The low-pass, anti-aliasing characteristics of filter

440

are designed, in accordance with known techniques, based on a rate at which normalized emission signal

312

will be digitally sampled. This sampling rate, in turn, is based on a desired scan rate and a desired resolution of the scanned image. These considerations are now described in relation to

FIGS. 5A and 5B

.

FIG. 5A

is a simplified graphical representation of a probe feature for detection and processing by scanner

300

. Generally, the term probe feature is used in this context to refer to a region of a probe array made up one or more probes that are designed to detect a same target or portion of a target, or to provide a control to verify the detection of that target or portion of a target. In a spotted probe array, a probe feature may be a single spot of a biological material intended to contain one species of polymer. In a synthesized probe array, a probe feature may include many thousands of oligonucleotides designed for a perfect match with a same target sequence, or a probe feature may include thousands of nucleotides designed for a mismatch (for control purposes) with a same target sequence.

FIG. 5A

shows idealized probe feature

500

in the form of a single circular spot that may be deposited, for example, by an Affymetrix® 417™ or 427™ Arrayer. It will be understood that a probe feature may be any shape, including irregular shapes. Spot

500

may be, as an illustrative example, one of features

230

of the spotted probe array of

FIGS. 2A and 2B

. In the manner described above, objective lens

145

scans over probe feature

500

(and, typically, other probe features of the probe array) in bi-directional arcs. An illustrative scan

520

is shown in FIG.

5

A. It will be understood that

FIG. 5A

is not necessarily drawn to scale, and that the ratio of the radius of the arc of scan

520

to the radius of feature

500

is illustrative only.

Also, probe feature

500

moves under objective lens

145

, as represented by direction

244

of

FIGS. 2B and 5A

that, as noted, may be referred to for convenience as the y direction. Thus, in the illustrated implementation, arm

200

scans in an arc in one direction, shown as left-to-right scan

520

in FIG.

5

A. Translation stage

242

is then moved incrementally by a stepping motor (not shown) in y-direction

244

and arm

200

then scans back in the opposite direction, shown as right-to-left arcuate scan

522

. Translation stage

242

is again moved in direction

244

, and so on in scan-step-scan-step sequences. In this example, the terms scan or scan line thus will be understood to apply to a scan of a line or an arc, typically each scan referring to the movement along the line or arc in one direction. However, a scan may also be repeated in one direction, or bi-directionally, multiple times, and the terms scan or scan line may refer to these repeated scans in some contexts. Returning to the present specific example in which scans

520

and

522

are referred to as separate scans, the distance between these scans thus corresponds to the distance that translation stage

242

is moved in each increment, although it will be understood that the distance shown in

FIG. 5A

is not necessarily to scale and is illustrative only. It will be understood that any other combination of scanning and stepping is possible in alternative implementations, and that scanning and moving of translation stage

242

may occur at the same or at overlapping times in some implementations. Translation stage

242

need not be stepped in some implementations, but may, for example, be moved continuously.

FIG. 5B

is a plot having a pixel clock axis

530

showing when clock pulses

532

occur. Axis

530

in the illustrated implementation is a spatial axis; that is, each of clock pulses

532

occurs in reference to the radial location of arm

200

during each scan, as described in greater detail below. Thus, with reference to the position of translation stage

242

indicated by scan

520

, a clock pulse

532

A occurs prior to arm

200

passing over feature

500

from the left as shown in

FIGS. 5A and 5B

. (For sake of clarity of illustration only, vertical dotted lines are provided between FIGS.

5

A and

5

B to illustrate this alignment.) As another example, clock pulse

532

C occurs with respect to scan

520

when arm

200

has just passed over portions of feature

500

indicated by pixel areas A and K. These areas are referred to as pixel areas because a digital value is assigned to each such area in the illustrated implementation based on the strength of a filtered emission signal associated with that area. In accordance with known techniques, clock pulses

532

enable the digital sampling of the filtered emission signal.

As will be appreciated by those of ordinary skill in the relevant art, the Nyquist criterion may be applied to determine the appropriate low-pass characteristics of filter

430

based on a desired sampling rate. As noted, clock pulses

532

are spatially rather than temporally determined in the illustrated implementation. Moreover, in some aspects of the illustrated implementation, galvanometer

216

is driven by a control signal provided by computer

350

such that the velocity of arm

200

in x-direction

243

is constant in time during those times when arm

200

is over probe feature

500

(and, typically, over other features of the probe array being scanned). That is, dx/dt is a constant (and thus the angular velocity varies) over the probe-scanning portions of each arc and, in particular, it is a constant during the times when clock pulses are generated to enable digital sampling. As is evident, dx/dt must be reduced to zero between each successive scan, but this deceleration and reversal of direction takes place after arm

200

has passed over the probe feature (or, more generally, the probe array). The design and implementation of a galvanometer control signal to provide constant dx/dt are readily accomplished by those of ordinary skill in the relevant art.

Thus, the approximate sampling rate may readily be calculated based on the desired scanning speed (dx/dt) and desired pixel resolution. To provide an illustrative example, a spot deposited by an Affymetrix® 417™ Arrayer typically has a diameter of approximately 200 microns. Spotted probe arrays made using this instrument typically may be deposited over a surface having a width of about 22 millimeters on a microscope slide that is 25 millimeters wide. In order to achieve pixel resolution of about 10 microns, a sampling rate of about 160 kHz is sufficient for scanning speeds typical for scanners used with respect to these probe arrays, such as the Affymetrix® 428™ scanner. Other sampling rates, readily determined by those of ordinary skill, may be used in other applications in which, for example, different scanning speeds are used and/or different pixel resolutions are desired. The desired pixel resolution typically is a function of the size of the probe features, the possibility of variation in detected fluorescence within a probe feature, and other factors. The desired scanning speed typically is a function of the size of the probe array to be scanned, the amount of a time that a user may wish to wait for the scanning to be completed, the response characteristics of the fluorophores, the response characteristics of emission detector

115

, the response and operational characteristics of galvanometer

216

, and a variety of other factors.

In order to avoid aliasing errors, filter

440

should have a low-pass cutoff frequency of one half or less of the sampling frequency, as those of ordinary skill will appreciate based on the Nyquist criterion. Thus, for example, filter

440

as implemented in the Affymetrix® 428™ scanner is designed in accordance with known techniques to have a cut-off frequency of 33 kHz in some implementations and 67 kHz in other implementations. As will be evident to those of ordinary skill in the relevant art, the lower cut-off frequency achieves somewhat greater smoothing at the expense of a potential loss in signal accuracy. In implementations in which the command signal driving galvanometer

216

is not designed to provide constant dx/dt but rather, for example, a constant angular velocity over the probe-scanning area, the appropriate cut-off frequency dictated by the Nyquist criterion should take into account variation in the sampling rate for different portions of the arc assuming that it is desired to provide clock pulses that are constant in the x direction.

Noise compensation module

310

A also includes excitation signal filter

430

that has the same design characteristics as, i.e., it is matched with, emission signal filter

440

. The reason for matching filters

430

and

440

with each other is to provide that the delay through both filters is the same. If the delays were different, then filtered excitation signal

432

and filtered emission signal

442

would no longer be spatially correlated. That is, a value of filtered excitation signal

432

at a particular time t would represent the excitation of a particular fluorophore at a position p, but the value of filtered emission signal

442

at the same time t would represent the emission of a fluorophore that was excited at a position either before or after position p in the scanning arc.

Loss of spatial correlation could interfere with techniques described herein to normalize emission signals to compensate for noise in laser excitation signals. As described below, normalized emission signal

312

is determined in this implementation by adjusting filtered emission signal

442

by a normalization factor

452

. Factor

452

is determined by comparing a nominal excitation value with filtered excitation signal

432

. The nominal excitation value can be derived in a variety of such as by low-pass filtering or by taking an average or other statistical measure of large numbers of samples over a relatively long period so that the impact of noise components is minimized. Also, a nominal value can be predetermined by manual calibration or other techniques, and the value stored in calibration data

376

for reference. In essence, emission signals are adjusted to compensate for variations in the excitation signals that gave rise to them. If spatial correlation is not maintained, then this cause and effect relationship may be lost and erroneous adjustments may result. However, approaches other than matched filters may be taken to provide spatial correlation. For example, in alternative embodiments, any mismatches in the delays of filters

430

and

440

may be compensated for either in hardware (e.g., by introducing a compensating delay with respect to one or the other signal in accordance with known techniques) or in software (e.g., by realigning sampled emission and excitation signals to offset delays).

FIGS. 5A-5D

further illustrate these points. In these figures, it is illustratively assumed that executables

372

initiates clock pulse

532

D at a time t. This clock event is determined by the receipt of a signal from transducer

215

indicating that excitation beam

135

is located over a radial position in the scanning arc shown with reference to scan

520

as radial position

525

C′. (Transducer

215

provides a signal with the same value when beam

135

is located over the same radial position for scan

522

, which is labeled as radial position

525

C″.) Executables

372

retrieves from galvo position data table

378

a value of the signal from transducer

215

that corresponds to radial positions

525

C′ and

525

C″. This value also corresponds to a position on each of every other scan that intersects with constant radial position line

525

C of

FIG. 5A

, which is parallel to direction

244

of translation stage

242

.) This retrieved value is compared to the signal from transducer

215

until it is determined that the values are equal, causing executables

372

to initiate clock pulse

532

D. In the illustrated implementation, the radial position values in galvo position data table

378

are predetermined so that each of constant radial position lines

525

(e.g.,

525

A,

525

B, through

525

K of the example of

FIG. 5A

) are positioned at an equal distance perpendicular to direction

244

. This feature facilitates the software translation of pixels from polar coordinates to Cartesian coordinates.

Thus, returning to the example of clock pulse

532

D initiated at time t, it is illustratively assumed that filtered excitation signal

432

has a value at that time that is shown in

FIG. 5D

as filtered excitation voltage

580

D. Voltage

580

D therefore may be spatially correlated with radial position

525

C′ (and with the position at time t of translation stage

242

). However, because voltage

580

D has been filtered and thus phase delayed, it typically corresponds with values of gain-normalized excitation signal

422

that occurred earlier in time and therefore at a location on scan

520

to the left of radial position

525

C′. To take into account this spatial translation, it is provided that adjusted emission signal

462

is phase delayed by the same amount. As noted, this result is accomplished by providing that the phase delay characteristics of filters

440

and

430

are matched. For example, the same electrical components may be used, particularly if gain generator

490

provides that adjusted emission signal

462

has approximately the same dynamic range as gain-normalized excitation signal

422

. Thus, because the phase delays for both excitation and emission signals are the same, the value of filtered emission signal

442

sampled as the result of the initiation of clock pulse

532

D, shown as illustrative voltage

550

D in

FIG. 5C

, corresponds spatially with excitation voltage

580

D. Alternatively stated, the matched filters provide that a fluorophore located at a position on probe feature

500

represented by position

525

C′, which was excited by voltage

580

D, emitted a signal represented by voltage

550

D, wherein both voltages were sampled at a same time.

A further desirable characteristic to be considered in the design of filters

430

and

440

is to provide constant group delay of the filters' input signals irrespective of the frequency components of those inputs. That is, it generally is desirable that the phase delay introduced by filters

430

and

440

be a determinable constant based on the filters' design rather than the characteristics of the input signal. Alternatively stated, it generally is desirable for bi-directional scanning that the rise and fall response characteristics of each of the filters be symmetrical. In the illustrated implementation, these characteristics are accomplished by providing that both of filters

430

and

440

are linear-phase filters, such as Bessel filters. In particular, filters

430

and

440

are high-order Bessel filters, such as 6

th

order or higher, and preferably 11

th

order or higher, Bessel filters. The advantage of providing the feature of symmetrical, matched filters may be illustrated with respect to the example of

FIGS. 6A-6E

.

FIG. 6A

shows a simplified input waveform

600

such as may be provided as input to filter

440

, i.e., adjusted emission signal

462

. Input waveform

600

has simulated high-frequency noise components that are included within repeating dual pulses

610

A through

610

G (generally and collectively referred to hereafter for convenience as noise pulses

610

). It will be understood, however, that noise components of signal

462

(and of signal

422

) typically are not regular and are more complex in frequency and amplitude.

Output waveform

615

of

FIG. 6B

is a graphical representation of the output of filter

440

in response to input waveform

600

, assuming that filter

440

is not a linear-phase filter. For example, filter

440

may be a Butterworth filter in this example. A peak

612

A is observable on waveform

442

A having a rising edge

616

A that is steeper and of a different shape than its falling edge

614

A; i.e., the rising and falling edges are not symmetrical. As is evident, the same asymmetry occurs in response to each of input pulses

610

, as indicated by output pulses

612

A through

612

H.

It is now illustratively assumed that output waveform

615

is the result of scan

520

in the left-to-right direction, and that a successive scan

522

in the opposite direction is made over a probe feature that has a constant concentration of fluorophores between and including the two scans. Equivalently, it may be assumed that the stepping motor does not advance translation stage

242

between the scans. To obtain the same result irrespective of the direction of the scan, output waveform

615

should have the same shape irrespective of which direction the scan was taken (although the waveforms will be displaced in time by a factor of twice the phase delay of the filter). However, as can be seen from

FIG. 6B

, this desired symmetry will not occur since the rising and falling edges of pulses

612

are asymmetrical. Improved smoothing and perhaps greater symmetry can be accomplished by higher-order filters that do not have the characteristic of constant group delay, as shown by FIG.

6

C. Output waveform

620

of

FIG. 6C

is the response of such a filter to input waveform

600

. Pulses

622

of

FIG. 6C

are smoother and somewhat more symmetrical than pulses

612

of

FIG. 6B

, but the problem of directional-dependent inconsistency remains.

In contrast, output waveform

630

of

FIG. 6D

is the simulated response of filter

440

implemented as a Bessel filter, and it may be observed that the resulting pulses are substantially symmetrical. For example, rising edge

636

A is substantially the mirror image of falling edge

634

H. The degree of symmetry generally may be improved by implementing filter

440

(and providing matched filter

430

) as higher-order Bessel filters, as shown by output waveform

640

of FIG.

6

E.

The advantages of using symmetrical filters for bi-directional scanning may further be appreciated with reference to

FIGS. 7A-7C

and

8

A-

8

C.

FIG. 7A

is a graphical representation of an input waveform

700

that is illustratively assumed to be provided to asymmetrical emission signal filter

440

. Waveform

800

of

FIG. 8A

is the same as waveform

700

, except that it is illustratively assumed to be provided to filter

440

implemented as a symmetrical filter, such as Bessel filters. Both waveforms

700

and

800

are idealized for clarity of illustration in that no noise is present and the pulses are shown as simple step functions.

FIG. 7B

shows output waveform

739

resulting from a scan

720

in a first direction, and

FIG. 7C

shows output waveform

749

resulting from a scan

522

in an opposite direction, both in the context of an implementation of filter

440

(and thus filter

430

to provide matching) as asymmetrical filters. Similarly,

FIG. 8B

shows output waveform

839

resulting from a scan

820

in a first direction, and

FIG. 8C

shows output waveform

849

resulting from a scan

522

in an opposite direction, both in the context of an implementation of filters

430

and

440

as symmetrical filters. The voltage waveforms of

FIGS. 7A-7C

and

8

A-

8

C are shown as functions of consecutive clock pulses

732

and

832

, respectively, on spatial pixel clock axes.

With reference to

FIG. 7B

, output waveform

739

results from scanning in left-to-right scan direction

720

in relation to spatial pixel clock axis

730

. That is, input waveform

700

results from scanning at positions to the left of the radial position represented by pixel clock position

732

D and proceeding toward the radial position represented by pixel clock position

732

K. As seen from output waveform

739

, the portion of the rising edge of that waveform between positions

732

D and

732

E is of a different shape than the portion of the falling edge between positions

732

F and

732

G. This difference is graphically represented by pixels

735

aligned below corresponding pixel clock positions. For example, if waveform

739

were sampled by a pixel clock pulse corresponding to position

732

D, the sampled value would be relatively small. For convenience, a small value (e.g., relatively low intensity of filtered emission signal

442

) is shown as a dark pixel, such as pixel

735

A. If waveform

739

were sampled at position

732

E, at the top of the rising edge, the sampled value would be relatively large, as represented by white pixel

735

B indicating a high intensity emission signal. A sample taken at position

732

F along the falling edge provides a middle value, as represented by pixel

735

C in cross hatching. The area scanned in direction

720

between positions

732

D and

732

K would be represented by the following sequence of pixel intensities as indicated by pixels

735

: dark-white-mid-dark-dark-white-mid-dark. Each level of intensity is indicative of a different degree of emission by fluorophores at locations corresponding to the pixel clock positions (although, as noted, a phase delay is anticipated). In

FIG. 7C

it is illustratively assumed that the same input waveform

700

is provided to the same filter, except that the scan is in direction

722

, i.e., starting from position

732

K and moving toward position

732

D. Because of the asymmetry of the rising and falling edges after filtering, the samples taken in this reverse positional order result in a different sequence of pixel intensities, as indicated by pixels

745

: dark-mid-white-dark-dark-mid-white-dark.

Two observations can thus be made by comparing these two sequences. One observation is that the two pulses of input waveform

700

are measured differently based on the direction of scanning: in the

720

direction the pulses are measured as white mid, whereas in the

722

direction the same pulses are measured as mid white. That is, in successive bid-directional scans, spatial transitions in input values provide inconsistent sampling results. The second observation is that the measured pulses are shifted spatially by twice the phase delay of the filter. This phase delay need not, and generally will not, be an integer number of pixel positions, but is a real number representing a spatial shift determined by the phase delay characteristics of the filter.

The results of these effects can be seen in

FIG. 7D

, which is a simplified graphical representation of pixels resulting from successive bi-directional scans of a probe feature in which adjusted emission signal

462

is represented by input waveform

700

for all scans in both directions. The pixels are aligned spatially along pixel clock axis

730

, as in

FIGS. 7B and 7C

. In order to accommodate the phase delay introduced by emission filter

440

, the spatial width of the scan in either direction (a distance D equal to the distance between ten clock pulses in this example) is greater than the spatial width of the probe feature being scanned (eight clock pulses); i.e., the feature can be said to have been over-scanned in both directions. Although the phase delay in this example is shown as equal to the distance between successive clock pulses, this is only an illustrative example. As noted, the delay in general is measured as a real number that may be expressed as fractions (any real number) of distances between clock pulses, i.e., fractional pixels.

FIG. 7E

is a graphical representation of the pixels of

FIG. 7D

shifted so as to graphically compensate for the effects of phase delay. The pixels at the beginning and end of each scan have been eliminated from this representation so that the external edges of the feature representation can be more clearly seen. This shifted representation may, for example, be presented to users in a graphical user interface, or the data associating the pixels in this manner may be stored in computer

350

for further image and/or signal processing. These tasks may be accomplished in accordance with any of a variety of conventional techniques well known to those of ordinary skill in the art whether implemented in hardware, software, or a combination thereof. As indicated by

FIG. 7E

, transient pixel intensities appear indistinct. In particular, the left hand edge of the feature as represented by input waveform

700

, as detected at the output of asymmetric filter

440

of this example, has a zipper-like pattern of alternating high and mid-intensities shown by vertically alternating pixels

735

B and

745

B. The right hand edge has the same distorted quality, as shown by vertically alternating pixels

735

G and

745

G. The same distortion is present at transient points within the feature, as indicated by vertically alternating pixels

735

C and

745

C, and by vertically alternating pixels

735

F and

745

F.

FIGS. 8D and 8E

present the same information as described above with regard to

FIGS. 7D and 7E

, respectively, except that

FIGS. 8D and 8E

are based on the assumption of

FIGS. 8B and 8C

that filter

440

is a symmetrical filter. As is indicated by

FIGS. 8D and 8E

, a phase delay is also introduced by the symmetric filter. However, transients in the intensity of filtered emission signal

442

are not distorted. Rather, as indicated by the vertical alignment of consistently high-intensity pixels, the zipper effect is avoided and the transient points are clear.

Returning now to

FIG. 4

, two additional components of noise compensation module

310

A remain to be described. Normalization factor generator

450

compares filtered excitation signal

432

to excitation reference

476

. The purpose is to provide a normalization factor

452

that provides a measure of a deviation of filtered excitation signal

432

from a nominal value. This deviation typically is due to noise in excitation beam

135

generated by excitation source

120

(e.g., the laser operational at the period of interest) that thus appears in excitation signal

194

and gain-normalized excitation signal

422

and, in filtered form, in filtered excitation signal

432

. The deviation may also be due, in some implementations, to long-term drift in excitation beam

135

. For example, lasers may degrade over periods of weeks, months, or years so that the magnitude of their steady state output declines. This long-term drift, which may be positive or negative, may be compensated for by adjusting the gain of the appropriate one of gain generators

410

B. Alternatively, the excitation reference component of calibration data

376

may be adjusted accordingly. In either case, if the long-term drift reaches a threshold level, a user may be advised that excitation source

120

has degraded and should be repaired or replaced. The threshold level may, for example, be a predetermined percentage of a nominal laser output value supplied by the laser manufacturer and stored as a component of calibration data

376

. The notification to the user may be accomplished for example by an appropriate graphical user interface of computer

350

, all in accordance with conventional techniques well known to those of ordinary skill in the relevant art.

With respect to the objective of compensating for laser noise, excitation reference

476

typically, but not necessarily, represents a nominal expected value of filtered excitation signal

432

over a time period substantially greater than that of the lowest expected noise frequency, but shorter than the time over which significant laser drift typically occurs. This period is selected such that an average or other statistical measure of signal

432

may reliably be determined. For example, monitored filtered excitation signal

434

, equal to or representative of filtered excitation signal

432

, may be provided to computer

350

for digital sampling over a period of one or more scans. In accordance with known techniques, the sampled signal may be statistically processed to provide, for example, an average or nominal value of signal

432

for that scan that may be used as excitation reference

476

for the next scan. Alternatively, each scan may be done twice: once to determine an average value and once to determine actual values including noise. Thus, the value of excitation reference

476

may be updated as frequently as every scan or less. Alternatively, reference

476

may be predetermined based on an initial calibration of excitation source

120

, or based on manufacturer's specifications, and stored as a component of calibration data

376

. In yet another alternative implementation, low-pass filter

431

may be used to remove all expected noise components from filtered excitation signal

432

, and this low-frequency signal, shown as

476

′, may be used as an excitation reference. This implementation is represented in dashed lines in

FIG. 4

to indicate its optional application.

As will now be appreciated by those of ordinary skill in the art, many other techniques are possible in hardware, software, or both, for providing an excitation reference that represents filtered excitation signal

432

with noise components substantially removed. In many cases, moreover, it is desirable to provide that, at a standard value of gain generator

490

, each implementation of each excitation source

120

of each scanner

300

provides a standard value of filtered emission signal

442

when exciting a standard fluorophore sample. In some implementations, therefore, a known concentration of fluorophores is prepared as a calibration slide to be scanned by each of a series of manufactured scanners

300

. Gain generator

490

is set at a nominal, standard, value, preferably one determined with respect to the dynamic range of the fluorophore. A photomultiplier tube or other detector is set to measure filtered emission signal

442

. In some implementations, adjusted emission signal

462

may be measured instead. The power of excitation beam

135

is also measured by, for example, measuring filtered excitation signal

432

(with the corresponding gain generator

410

set to a standard value) in accordance with any of a variety of conventional measuring techniques. For each of excitation sources

120

, e.g., for each of lasers

120

A and

120

B of the illustrated implementation, the excitation source is adjusted to increase or decrease excitation beam

135

until the measured value of filtered emission signal

442

(or of signal

462

) is a standard value. The value of filtered excitation signal

432

at this calibration setting is stored in calibration data

376

and thenceforth serves as excitation reference

476

for that excitation source

120

for that scanner

130

, or as a basis for determining an appropriate excitation reference. In alternative implementations, instead of adjusting the excitation source to increase or decrease beam

135

, the adjustment may be made to gain generator

490

, and/or to the gain of emission detector

115

. In either case, excitation reference

476

is a constant value, and is not determined by, for example, averaging scans or low-pass filtering as described above. Rather, reference

476

is a calibrated value unique to the instrument and, generally, constant for the life of the instrument or a period of time over which consistent experimental results are desired. A significant advantage of the calibration approach leading to a constant excitation reference

476

for each scanner

130

instrument is that, even if excitation source

120

degrades over time, a user will be able to replicate experiments and obtain the same measurements over time.

In one implementation, normalization factor generator

450

may be an analog multiplier/divider device, such as is available from a variety of commercial suppliers including Analog Devices, Inc. of Norwood, Mass., or one of numerous other analog and/or digital devices that perform multiplication, division, and/or comparative functions. In the illustrated implementation, generator

450

multiplies or divides filtered excitation signal

432

and excitation reference

476

(or

476

′) to provide a ratio between the two. For example, if reference

476

has a value of 1.00 and the value of signal

432

is 1.25, then the value of normalization factor

452

at that time (hereafter, for convenience, the instantaneous value) is 1.00/1.25=0.80. That is, in this illustrative implementation, the comparison between a steady state measure of signal

432

and the instantaneous value of signal

432

is provided by dividing an average value of signal

430

by the instantaneous value of signal

430

. Any of various other statistical comparisons may be used in alternative implementations, as will now be appreciated by those of ordinary skill in the relevant art.

Comparison processor

460

applies normalization factor

452

to filtered emission signal

442

. Comparison processor

460

may also any of numerous analog multiplier/divider device or other devices such as noted above with respect to generator

450

. In the illustrated implementation, processor

460

multiplies the instantaneous value of filtered emission signal

442

by normalization factor

452

to provide normalized emission signal

312

. Thus, in the illustrated implementation, generator

450

and processor

460

together implement a function that may be represented as: signal

312

(

t

)=signal

442

(

t

)*(average signal

432

/signal

432

(

t

)) where (t) indicates instantaneous values over time.

Signal

312

may in some implementations be provided to computer

350

for sampling as enabled by pixel clock pulses generated by computer

350

, as described above. In other implementations, the generation of pixel clock pulses and their application to signal

312

may be done by an appropriate device located in scanner

300

. For example, as shown in

FIG. 3

, pixel clock

305

may be implemented in scanner

300

by a complex programmable logic device (CPLD) such as is commercially available from Altera Corporation of San Jose, Calif., and other suppliers.

FIG. 9

is a functional block diagram showing an alternative implementation in hardware and software of the functions just described with respect to the primarily hardware implementation of FIG.

4

. In particular, the functions of elements

910

,

920

,

930

,

940

, and

960

of

FIG. 9

are similar to those described above with respect to elements

410

,

420

,

430

,

440

, and

460

of

FIG. 4

, respectively. However, in the implementation of

FIG. 9

, the functions described above with respect to normalization factor generator

450

and comparison processor

460

are performed by computer

350

. The result in the implementation of

FIG. 9

is normalized emission signal data

374

that provide information similar to that contained in normalized emission signal

312

as shown in FIG.

4

.

It will be understood that the embodiment of computer

350

shown in

FIGS. 3

,

4

and

9

is exemplary only, and that many alternative implementations are possible. For example, the functions of computer

350

may be performed by one or more components of scanner

300

rather than being performed by an external computer instance, scanner

300

may include a microprocessor with associated firmware for performing some or all of the functions ascribed herein to computer

350

.

In the illustrated embodiment, computer

350

may be located locally to scanner

300

, or it may be coupled to scanner

300

over a local-area, wide-area, or other network, including an intranet and/or the Internet. Computer

350

may be a personal computer, a workstation, a server, or any other type of computing platform now available or that may be developed in the future. As shown in

FIG. 4

, computer

350

includes a process controller

462

for performing control and analysis functions with respect to scanner

300

as described below. Typically, computer

350

also includes known components such as CPU

355

, operating system

360

, system memory

370

, memory storage devices

380

, and input-output controllers

375

, all of which typically communicate in accordance with known techniques such as via system bus

390

. In the illustrated implementation, computer

350

also includes digital signal processor board

380

, which may be any of a variety of PC-based DSP controller boards, such as the M44 DSP Board made by Innovative Integration of Simi Valley, Calif. A variety of other components may be included in computer

350

, as is well known by those of ordinary skill in the relevant art.

In reference to

FIG. 9

, filtered excitation signal

932

, corresponding to filtered excitation signal

432

described above, is provided to line driver

931

that, in accordance with known techniques, provides signal

932

′ to DSP board

380

of computer

350

. Similarly, filtered emission signal

942

, corresponding to filtered emission signal

442

described above, is provided to line driver

941

that provides signal

942

′ to DSP board

380

. In accordance with known analog-to-digital sampling techniques, board

380

samples signals

932

′ and

942

′ based on pixel clock sampling pulses. These pulses may be provided by pixel clock CLPD

305

, or they may be generated by aspects of executables

372

by comparing radial position information from galvo position transducer

215

with data in galvo position data table

378

. In the former implementations, CLPD

305

performs the functions of computer

350

, and may also store data such as that in table

378

. Optionally, prior to sampling, board

380

may include anti-aliasing filters (such as filters

1030

and

1040

of

FIG. 10

) designed in accordance with the Nyquist criterion as noted above to further ensure that aliasing errors do not occur when signals

932

′ and

942

′ are sampled.

In this alternative implementation software-implemented functional elements of executables

372

perform the functions described in reference to

FIG. 4

with respect to the operations of normalization factor generator

450

and comparison processor

460

. That is, executables

372

, in cooperation with other elements of computer

350

such as CPU

355

and operating system

380

, generates a compensation factor that is based on a comparison between a reference excitation value and, in some implementations, each sampled excitation value. Executables

372

then applies this factor to each corresponding sampled emission signal to provide normalized emission signal data corresponding to each sample of the emission signal. Thus, the functional elements of executables

372

comprise sets of software instructions that cause the described functions to be performed. These software instructions may be programmed in any programming language, such as C++ or another high-level programming language. Executables

372

may therefore be referred to as a set of scanner control and analyzing instructions, and its functional elements may similarly be described, for example, as sets of normalization factor generating instructions (as represented by generator

1050

) and comparison processing instructions (as represented by processor

1060

).

These operations are shown in greater detail in

FIG. 10

, which is a functional block diagram of aspects of computer

350

that generate normalization factors for each sampled excitation signal and applies those factors to filtered emission signals to obtain normalized emission signal data. In accordance with any of a variety of known techniques, analog to digital converter

1035

digitizes samples of signals

932

′ to generate excitation samples

1037

, which are provided by to normalization factor generator

1050

of executables

372

. Similarly, analog to digital converter

1045

digitizes samples of signals

942

′ to generate emission samples

1047

, which are provided by to comparison processor

1060

of executables

372

. For ease of reference, a pair of samples

1037

and

1047

sampled according to the same sampling pulse will be referred to as a particular instance of those samples.

Excitation reference

1076

of calibration data

376

also is provided to generator

1050

. Reference

1076

is a reference excitation value derived in accordance with any the techniques described above with respect to excitation reference

476

.

Generator

1050

performs functions similar to those described above with respect to generator

450

. For example, in some implementations, generator

1050

determines an instance of compensation factor

1052

by dividing reference

1076

by the value of excitation sample

1037

for that instance. This instance of factor

1052

is multiplied by the corresponding instance of emission sample

1047

to obtain the corresponding instance of normalized emission signal data

374

. Thus, in the illustrated and non-limiting implementation, each instance (I) of data

374

is derived in accordance with the algorithm: data

374

(I)=sample

1047

(I)* (reference

1076

/sample

1037

(I)) Typically, generator

1060

and processor

1070

are implemented as software instructions in any appropriate programming language, such as C++, and compiled for inclusion in executables

372

that are executed on computer

350

of the illustrated implementation. In particular, system memory

370

of computer

350

may be any of a variety of known or future memory storage devices. Examples include any commonly available random access memory (RAM), magnetic medium such as a resident hard disk or tape, an optical medium such as a read and write compact disc, or other memory storage device. Memory storage devices

380

may be any of a variety of known or future devices, including a compact disk drive, a tape drive, a removable or internal hard disk drive, or a diskette drive. Such types of memory storage devices

380

typically read from, and/or write to, a program storage medium (not shown) such as, respectively, a compact disk, magnetic tape, removable or internal hard disk, or floppy diskette. Any of these program storage media, or others now in use or that may later be developed, may be considered a computer program product. As will be appreciated, these program storage media typically store a computer software program and/or data. Computer software programs, also called computer control logic, typically are stored in system memory and/or the program storage medium used in conjunction with memory storage devices

380

.

In some implementations, a computer program product is described comprising a computer usable medium having control logic (computer software program, including program code) stored therein. The control logic, when executed by processor

355

, causes processor

355

to perform the functions of scanner control and analysis executables

372

, including generator

1050

and processor

1060

. In other embodiments, these and other functions of executables

372

may be implemented primarily in hardware using, for example, a hardware state machine. Implementation of the hardware state machine so as to perform the functions of executables

372

described herein will be apparent to those skilled in the relevant art.

Having described various embodiments and implementations, it should be apparent to those skilled in the relevant art that the foregoing is illustrative only and not limiting, having been presented by way of example only. Many other schemes for distributing functions among the various functional elements of the illustrated embodiment are possible. The functions of any element may be carried out in various ways in alternative embodiments.

Also, the functions of several elements may, in alternative embodiments, be carried out by fewer, or a single, element. For example, excitation signal filter

430

emission signal filter

440

of the implementation shown in

FIG. 4

may, in other implementations, be replaced by a single anti-aliasing filter that operates on the output of comparison processor

460

to provide normalized emission signal

312

. As another example, the functions of gain generators

410

could alternatively be performed by multiplexer

420

, or by computer

350

.

Similarly, in some embodiments, any functional element may perform fewer, or different, operations than those described with respect to the illustrated embodiment. Also, functional elements shown as distinct for purposes of illustration may be incorporated within other functional elements in a particular implementation. Furthermore, the sequencing of functions, or portions of functions, generally may be altered. For instance, the functions of gain generator

490

may be performed after those of emission signal filter

440

.

Certain functional elements, files, data structures, and so on, are described in the illustrated embodiments as located in system memory

370

of computer

350

. In other embodiments, however, any or all of these may be located on, or distributed across, computer systems or other platforms that are co-located and/or remote from each other. In addition, it will be understood by those skilled in the relevant art that control and data flows between and among functional elements and various data structures may vary in many ways from the control and data flows described above. More particularly, intermediary functional elements may direct control or data flows, and the functions of various elements may be combined, divided, or otherwise rearranged to allow parallel processing or for other reasons. Also, intermediate data structures or files may be used and various described data structures or files may be combined or otherwise arranged. Numerous other embodiments, and modifications thereof, are contemplated as falling within the scope of the present invention as defined by appended claims and equivalents thereto.

Claims

1. A scanning system comprising:a scanner optics and detector arrangement including, an excitation source that generates an excitation beam, and an excitation signal generator to provide an excitation signal having a value representative of the excitation beam; and a compensation module operatively coupled to the scanner optics and detectors arrangement, for compensating for deviations in the excitation signal, the compensation module comprising: a normalization factor generator for generating a normalization factor representing a difference between a nominal excitation value representing a nominal expected value of the representative excitation value over a time period and the representative excitation value; and a comparison processor that adjusts, based on the normalization factor, emission value of a received emission signal, the emission value corresponding to the representative excitation factor, thereby generating a normalized emission signal having the adjusted emission value.
2. The scanning system of claim 1, wherein the compensation module further comprises:an emission signal filter for filtering the received emission signal to generate a filtered emission signal; and an excitation signal filter for filtering the excitation signal to generate a filtered excitation signal.
3. The scanning system of claim 2, wherein the emission signal filter performs anit-aliasing operations on the received emission signal so that the normalized emission signal can be digitized with substantially no aliasing errors.
4. The scanning system of claim 2, wherein the filtered excitation signal and the filtered emission signal are spatially correlated.
5. The scanning system of claim 4, wherein the excitation signal filter and emission signal filter have substantially the same processing delay.
6. The scanning system of claim 4, wherein the excitation signal filter and emission signal filter have substantially the same design characteristics.
7. The scanning system of claim 4, wherein mismatches in the delays of excitation signal filter and emission signal filter are compensated for by introducing a compensating delay with respect to one or the other signal.
8. The scanning system of claim 4, wherein mismatches in the delays of excitation signal filter and emission signal filter are compensated for by realigning sampled emission and excitation signals to offset the delays.
9. The scanning system of claim 2, wherein the compensation module further comprises:a gain generator that adjusts the gain of the received emission signal to provide an adjusted emission signal that is within a nominal range of amplitudes or alternatively has a nominal steady-state component, wherein the emission signal filter filters the adjusted emission signal.
10. The scanning system of claim 2, wherein the emission signal filter is a low-pass filter.
11. The scanning system of claim 10, wherein the low-pass filter has a low-pass cutoff frequency of one half or less than the frequency at which the normalized emission signal will be digitally sampled.
12. The scanning system of claim 2, wherein the emission signal filter comprises low-pass, anti-aliasing characteristics selected based on a rate at which the normalized emission signal will be digitally sampled.
13. The scanning system of claim 2, wherein the rise and fall response characteristics of each of the filters are symmetrical.
14. The scanning system of claim 2, wherein the filters are linear-phase filters.
15. The scanning system of claim 2, wherein, the nominal excitation value represents a nominal expected value of the filtered excitation signal over a time period substantially greater than that of the lowest expected noise frequency, and shorter than the time over which significant drift in the excitation source typically occurs.
16. The system of claim 1, wherein the nominal excitation value is determined based at least in part on a low-frequency component of the excitation signal.
17. The scanning system of claim 1, wherein the compensation module further comprises:a plurality of gain generators to provide adjustable gains to compensate for differences in the amplitude of excitation signal due to differences in the optical parameters of the scanner optics and detectors arrangement at different wavelengths of the excitation beam, wherein each gain generator is calibrated to one of a plurality of excitation sources that include the excitation source.
18. The scanning system of claim 17, wherein one or more of the adjustable gains are predetermined based on calibration protocols.
19. The scanning system of claim 2, wherein the compensation module further comprises:a multiplexer coupled to the plurality of gain generators to select a gain-normalized excitation signal generated by one of the gain generators which corresponds to the excitation source that generates the excitation beam.
20. The scanning system of claim 1, wherein the normalized emission signal is digitally sampled at a rate based on a desired scan rate and resolution.
21. The scanning system of claim 1, wherein the normalization factor generator is implemented entirely in hardware.
22. The scanning system of claim 1, wherein the excitation source is a laser.
23. The scanning system of claim 1, wherein the scanner optics and detectors arrangement is configured to direct the excitation beam to a probe feature comprising a region of a probe array including at least one probe designed to detect a same target or portion of a target, or to provide a control to verify the detection of that target portion thereof.
24. The scanning system of claim 23, wherein the probe array is a spotted probe array, and wherein the probe feature is a single spot of a biological material intended to contain one species of polymer.
25. The scanning system of claim 24, wherein the probe feature comprises a single circular spot deposited on a surface of the substrate by an arrayer.
26. The scanning system claim 25, wherein the substrate comprise one of the group consists of beads and optical fibers or other substrate or media.
27. The scanning system of claim 23, wherein the probe array is a synthesized probe array, and wherein the probe feature comprises over a thousand oligonucleotides designed for one of either a perfect match or a mismatch with a same target sequence.
28. The scanning system of claim 23, wherein the probe feature comprises at least one pixel area determined to be the area to which a digital value is assigned based on the strength of the normalized emission signal associated with that area.
29. The scanning system of claim 1, wherein the nominal excitation value is derived by low-pass filtering large numbers of samples of the excitation signal over a relatively long period.
30. The scanning system of claim 1, wherein the nominal excitation value is predetermined by manual calibration.
31. The scanning system of claim 1, wherein the deviations in the excitation signal are due to noise on the excitation signal.
32. The scanning system of claim 2, wherein the deviations in the excitation signal are due to long-term drift in the excitation signal.
33. A method for analyzing molecules, comprising:directing an excitation beam to a plurality of pixel areas on a surface having a plurality of probe locations each comprising a plurality of probe molecules; generating an excitation signal having an excitation value representative of a value of the excitation beam as directed to at least one of the plurality of pixel areas; detecting an emission signal having one or more emission values; correlating each emission value with one or more of the representative excitation values; providing at least one excitation reference value representing a nominal expected value of the excitation signal over time, generating a normalization factor representing the difference between the excitation reference value and the representative excitation value; and adjusting the emission value that is correlated with the representative excitation value based on the normalization factor.
34. The method of claim 33, further comprising:analyzing at least one pixel area based on the at least one adjusted emission value.
35. The method of claim 1, further comprising: filtering the excitation signal to generate a filtered excitation signal; and providing an emission signal.
36. The method of claim 35, wherein the time to perform the filtering of the excitation signal and the emission signal are substantially the same.
37. The method of claim 35, further comprising:compensating for differences in the amplitude of the excitation signal due to differences in the optical parameters of scanner optics and detectors that detect the emission signal to generate a gain-normalized excitation signal, and wherein the filtering of the excitation signal comprises filtering the gain-normalized excitation signal.
38. The method of claim 35, further comprising:adjusting the gain of the emission signal to provide an adjusted emission signal that is within a nominal range of amplitudes or alternatively has a nominal steady-state component, wherein the filtering of the correlated emission signal comprises filtering the adjusted emission signal.
39. The method of claim 35, wherein filtering the excitation signal comprises low-pass filtering the excitation signal, the step of filtering the correlated emission signal comprises low-pass filtering the correlated emission signal.
40. The method of claim 33, wherein providing at least one excitation reference value comprises:low-pass filtering a large number of samples of the excitation signal over a relatively a long period of time.
41. A method comprising:directing an excitation beam to a plurality of pixel locations on a substrate; determining one or more representative excitation values, each related to a value of the excitation beam as directed to at least one of the plurality of pixel locations; detecting an emission signal having one or more emission values; correlating each of the one or more emission values with one or more of the representative excitation values; comparing at least one representative excitation value to an excitation reference value to generate a normalization factor; and adjusting at least one emission value based on the normalization factor.
42. The method of claim 41, wherein one or more probes of a biological microarray are disposed in relation to the substrate.
43. The method of claim 42, wherein the one or more probes are disposed at different probe locations on a surface of the substrate.
44. The method of claim 41, wherein the substrate comprises a plurality of different polymer sequences coupled to a surface of the substrate.
45. The method of claim 41, wherein:the plurality of different polymer sequences comprises a plurality of different oligonucleotide sequences, wherein each of the different polymer sequences is coupled in a different probe location of the surface.
46. The method of claim 41, wherein:the excitation beam is a laser beam.
47. The method of claim 41, wherein:the plurality of pixel locations comprises one or more scan lines.
48. The method of claim 41, wherein:the representative excitation values are each related to a power of the excitation beam.
49. The method of claim 41, wherein generating the excitation signal comprises:directing the excitation beam to a dichroic mirror, and determining the representative excitation values based on a partial excitation beam that passes through the dichroic mirror.
50. The method of claim 41, wherein:the emission signal arises from the direction of the excitation beam to the plurality of pixel locations.
51. The method of claim 50, wherein:the emission signal comprises a fluorescent signal.
52. The method of claim 51, wherein:the substrate has a surface comprising a plurality of different probes at a plurality of probe locations on the surface of the substrate, at least one of the probes at a first probe location being bound to a fluorescently labeled receptor, wherein at least one of the emission values corresponds to an emission from the fluorescently labeled receptor responsive to the excitation beam being directed to the first probe location.
53. The method of claim 41, wherein correlating each of the one or more emission values comprising:spatially correlating the emission values with the representative excitation values.
54. The method of claim 53, wherein correlating each of the one or more emission values comprising:includes providing that each emission value is correlated with at least one representative excitation value that is related to a value of the excitation beam that gave rise to the emission value.
55. The method of claim 53, wherein:determining representative excitation values comprises determining a first representative excitation value related to a power of the excitation beam as directed to a first of the plurality of pixel locations; determining an emission signal comprises detecting an emission value arising from the direction of the excitation beam to the first pixel location; and correlating emission values comprises correlating the first emission value with the first representative excitation value.
56. The method of claim 41, wherein:the excitation reference value is based, at least in part, on at least one of the one or more representative excitation values.
57. The method of claim 41, wherein:the excitation reference value is based, at least in part, on a plurality of representative excitation values related to values of the excitation beam as directed to pixel locations in one or more scan lines.
58. The method of claim 41, further comprising:filtering the representative excitation values to provide one or more filtered representative excitation values; and wherein the excitation reference value is based, at least in part, on at least one of the one or more filtered representative excitation values.
59. The method of claim 41, wherein:the excitation reference value is based, at least in part, on a measured calibration value.
60. The method of claim 41, wherein:the excitation reference value is based, at least in part, on a predetermined specification value.
61. The method of claim 41, wherein adjusting at least one emission value comprises:determining a ratio between the excitation reference value and the at least one excitation value.
62. The method of claim 41, wherein adjusting the emission value comprises:multiplying or dividing the emission value by the normalization factor.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation of prior application Ser. No. 09/683,216 filed Dec. 3, 2001, now U.S. Pat. No. 6,490,533 issued Dec. 3, 2002, which claims priority to Provisional application 60/286,578 filed Apr. 26, 2001, the contents of which are hereby incorporated by reference herein in their entireties for all purposes. The present application is related to a U.S. Patent Application entitled System, Method, and Product for Pixel Clocking in Scanning of Biological Materials, application Ser. No. 09/683,217, and to a U.S. Patent Application entitled System, Method, and Product for Symmetrical Filtering in Scanning of Biological Materials, application Ser. No. 09/683,219, both of which are filed on Dec. 3, 2001 and both of which are hereby incorporated by reference herein in their entireties for all purposes.

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	60/286578	Apr 2001	US

Continuations (1)

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Parent	09/683216	Dec 2001	US
Child	10/304092		US

System, method, and product for dynamic noise reduction in scanning of biological materials

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Abstract