U.S. patent application number 13/209306 was filed with the patent office on 2011-12-08 for compensator for multiple surface imaging.
This patent application is currently assigned to ILLUMINA, INC.. Invention is credited to Jason Bryant, Dale Buermann, Wenyi Feng.
Application Number | 20110301044 13/209306 |
Document ID | / |
Family ID | 41256502 |
Filed Date | 2011-12-08 |
United States Patent
Application |
20110301044 |
Kind Code |
A1 |
Feng; Wenyi ; et
al. |
December 8, 2011 |
COMPENSATOR FOR MULTIPLE SURFACE IMAGING
Abstract
A system and method for imaging biological samples on multiple
surfaces of a support structure are disclosed. The support
structure may be a flow cell through which a reagent fluid is
allowed to flow and interact with the biological samples.
Excitation radiation from at least one radiation source may be used
to excite the biological samples on multiple surfaces. In this
manner, fluorescent emission radiation may be generated from the
biological samples and subsequently captured and detected by
detection optics and at least one detector. The detected
fluorescent emission radiation may then be used to generate image
data. This imaging of multiple surfaces may be accomplished either
sequentially or simultaneously. In addition, the techniques of the
present invention may be used with any type of imaging system. For
instance, both epifluorescent and total internal reflection methods
may benefit from the techniques of the present invention.
Inventors: |
Feng; Wenyi; (San Diego,
CA) ; Bryant; Jason; (Essex, GB) ; Buermann;
Dale; (Los Altos, CA) |
Assignee: |
ILLUMINA, INC.
San Diego
CA
|
Family ID: |
41256502 |
Appl. No.: |
13/209306 |
Filed: |
August 12, 2011 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
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12434495 |
May 1, 2009 |
8039817 |
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13209306 |
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61050522 |
May 5, 2008 |
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61138444 |
Dec 17, 2008 |
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Current U.S.
Class: |
506/4 ; 506/38;
506/6 |
Current CPC
Class: |
G02B 21/0024 20130101;
C12Q 1/6869 20130101; G02B 2207/113 20130101; G01N 21/6458
20130101; C12Q 1/6874 20130101; G01N 2021/0346 20130101; G01N
2021/6419 20130101; G01N 21/05 20130101; G01N 2021/6421 20130101;
C12Q 1/6825 20130101 |
Class at
Publication: |
506/4 ; 506/6;
506/38 |
International
Class: |
C40B 20/08 20060101
C40B020/08; C40B 60/10 20060101 C40B060/10; C40B 20/04 20060101
C40B020/04 |
Claims
1. A method for detecting a biological sample, comprising: (a)
detecting radiation emitted from a first emissive component of a
biological sample disposed on a first surface of a multi-surface
support structure using a detector; (b) inserting corrective optics
between the detector and the multi-surface support structure; and
(c) detecting radiation emitted from a second emissive component of
a biological sample disposed on a second surface of the
multi-surface support structure using the detector and the
corrective optics, wherein the first and second surfaces are in an
arrangement whereby one of the surfaces is disposed between the
detector and the other surface, wherein the corrective optics
reduce aberration of detection at one of the surfaces due to the
arrangement.
2. The method of claim 1, wherein the first surface is disposed
between the detector and the second surface.
3. The method of claim 2, wherein a fluid is present between the
two surfaces and the corrective optics reduce aberration due to the
fluid.
4. The method of claim 3, wherein the detector is initially
configured for diffraction-limited detection on the second surface
and the corrective optics are configured for diffraction-limited
detection on the first surface.
5. The method of claim 3, wherein the aberration comprises
spherical aberration.
6. The method of claim 1, wherein the first surface is disposed
between a source of radiation and the second surface.
7. The method of claim 1, wherein step (b) comprises inserting a
corrective device between an objective and the multi-surface
support structure, wherein the objective is disposed between the
detector and the multi-surface support structure.
8. The method of claim 1, wherein step (b) comprises inserting a
corrective lens between the detector and an objective, wherein the
objective is disposed between the detector and the multi-surface
support structure.
9. The method of claim 1, wherein steps (a) and (c) comprise
obtaining an image of the surfaces.
10. The method of claim 1, wherein steps (a) and (c) comprise
focusing a line of radiation to an area on the first or second
surface comprising the first or second emissive component.
11. The method of claim 1, wherein the emitted radiation is
detected using epifluorescent excitation.
12. The method of claim 1, wherein excitation radiation is directed
towards the first and second surfaces by total internal reflection
excitation.
13. The method of claim 1, wherein the first and second emissive
components comprise fluorescently tagged nucleic acids of a nucleic
acid sample.
14. The method of claim 1, wherein the first and second emissive
components comprise separate features in arrays of features on the
first and second surfaces, respectively.
15. The method of claim 1, wherein the multi-surface support
structure comprises a flow cell.
16. The method of claim 15, wherein the flow cell is mounted on a
detecting station.
17. The method of claim 16, further comprising: (d) repeating steps
(a) through (c) while maintaining the flow cell on the detecting
station.
18. The method of claim 17, wherein the repeating of steps (a)
through (c) comprises treating the flow cell with several repeated
cycles of a nucleic acid sequencing process.
19. The method of claim 17, wherein the repeating of steps (a)
through (c) comprises repeated steps of delivering one or more
reagents to the first and second emissive components of the
biological sample disposed on the first and second surfaces.
20. A system for detecting radiation on a multi-surface support
structure, comprising: a detecting station configured to position a
multi-surface support structure in a focus plane of an objective;
an optical train comprising the objective, detecting optics
configured to focus the optical train on a first surface of the
multi-surface support structure via the objective, and corrective
optics configured to focus the optical train on a second surface of
the multi-surface support structure and configured to reduce
aberration of detection at the first or second surface; a radiation
source configured to direct excitation radiation towards the first
and second surfaces; detection optics configured to capture emitted
radiation returned from the first and second surfaces via the
optical train; and a detector positioned to detect the captured
radiation.
21. The system of claim 20, wherein the corrective optics comprise
a corrective device configured to be removably inserted between the
objective and the multi-surface support structure.
22. The system of claim 20, wherein the corrective optics comprise
a corrective lens configured to be removably inserted between the
detector and the objective.
23. The system of claim 20, wherein the radiation source is
configured to direct the excitation radiation toward the first and
second surfaces at several different wavelengths, and the detection
optics and detector are configured to capture and detect the
emitted radiation returned in response to each wavelength.
24. The system of claim 20, wherein the multi-surface support
structure is present at the detecting station.
25. The system of claim 24, wherein first and second emissive
components of a biological sample are disposed on the first and
second surfaces, respectively.
26. The system of claim 25, wherein the multi-surface support
structure includes a fluid in an interior volume and in contact
with the first and second emissive components of the biological
sample.
27. The system of claim 20, wherein the first surface is disposed
between the radiation source and the second surface.
Description
CROSS REFERENCE TO RELATED APPLICATIONS
[0001] This application is a continuation of U.S. patent
application Ser. No. 12/434,495, entitled "Compensator for Multiple
Surface Imaging," filed May 1, 2009, which is herein incorporated
in its entirety by reference, and which claims priority of U.S.
Provisional Patent Application No. 61/050,522, entitled
"Multi-Surface Biological Sample Imaging System and Method," filed
May 5, 2008, which is herein incorporated in its entirety by
reference, and of U.S. Provisional Patent Application No.
61/138,444, entitled "Compensator for Multiple Surface Imaging,"
filed Dec. 17, 2008, which is herein incorporated in its entirety
by reference.
BACKGROUND
[0002] The present invention relates generally to the field of
imaging and evaluating analytical samples. More particularly, the
invention relates to a technique for imaging and evaluating
analytical samples on multiple surfaces of a support structure
using a compensator.
[0003] There are an increasing number of applications for imaging
of analytical samples on a support structure. These support
structures may include plates upon which biological samples are
present. For instance, these plates may include deoxyribonucleic
acid (DNA) and ribonucleic acid (RNA) probes that are specific for
nucleotide sequences present in genes in humans and other
organisms. Individual DNA or RNA probes can be attached at specific
locations in a small geometric grid or array on the support
structure. Depending upon the technology employed, the samples may
attach at random, semi-random or predetermined locations on the
support structure. A test sample, such as from a known person or
organism, can be exposed to the array or grid, such that
complementary genes or fragments hybridize to probes at the
individual sites on a surface of a plate. In certain applications,
such as sequencing, templates or fragments of genetic material may
be located at the sites, and nucleotides or other molecules may be
caused to hybridize to the templates to determine the nature or
sequence of the templates. The sites can then be examined by
scanning specific frequencies of light over the sites to identify
which genes or fragments in the sample were present, by
fluorescence of the sites at which genes or fragments
hybridized.
[0004] These plates are sometimes referred to as microarrays, gene
or genome chips, DNA chips, gene arrays, and so forth, and may be
used for expression profiling, monitoring expression levels,
genotyping, sequencing, and so forth. For example, diagnostic uses
may include evaluation of a particular patient's genetic makeup to
determine whether a disease state is present or whether
pre-disposition for a particular condition exists. The reading and
evaluation of such plates are an important aspect of their utility.
Although microarrays allow separate biological components to be
presented for bulk processing and individual detection, the number
of components that can be detected in a single experiment is
limited by the resolution of the system. Furthermore, the bulk
reagents used in some methods can be expensive such that reduced
volumes are desired. The present invention provides methods and
compositions that increase the efficiency of array based detection
to counteract these limitations. Other advantages are provided as
well and will be apparent from the description below.
BRIEF DESCRIPTION
[0005] The present invention provides a novel approach to
analytical sample imaging and evaluation that expands the use of
imaging and evaluation subsystems to multiple surfaces that support
samples. The support structure may, for instance, be a flow cell
through which a reagent fluid is allowed to flow and interact with
biological samples. Excitation radiation from at least one
radiation source may be used to excite the biological samples on
multiple surfaces. In this manner, fluorescent radiation may be
emitted from the biological samples and subsequently captured and
detected by detection optics and at least one detector. The
returned radiation may then be used to generate image data. This
imaging of multiple surfaces may be accomplished either
sequentially or simultaneously. In addition, the techniques of the
present invention may be used with any of a variety of types of
imaging systems. For instance, both epifluorescent and total
internal reflection (TIR) methods may benefit from the techniques
of the present invention. In addition, the biological samples
imaged may be present on the surfaces of the support structure in
random locations or in patterns.
[0006] Accordingly, the invention provides a method for imaging a
biological sample. The method includes detecting radiation emitted
from a first emissive component of a biological sample disposed on
a first surface of a flow cell using a detector. The flow cell is
mounted on an imaging station. The method also includes inserting
corrective optics between the detector and the flow cell. The
method further includes detecting radiation emitted from a second
emissive component of a biological sample disposed on a second
surface of the flow cell using the detector and the corrective
optics. The first and second surfaces are in an arrangement whereby
one of the surfaces is disposed between the detector and the other
surface. In addition, the corrective optics reduce aberration of
detection at one of the surfaces due to the arrangement. The steps
of the method are repeated while maintaining the flow cell on the
imaging station.
[0007] The invention further provides an imaging system for
detecting radiation on a multi-surface flow cell. The imaging
system includes a multi-surface flow cell having first and second
emissive components of a biological sample disposed on respective
first and second surfaces of the flow cell. The imaging system also
includes an optical train including an objective, imaging optics
configured to focus the optical train on the first emissive
component via the objective, and corrective optics configured to
focus the optical train on the second emissive component and
configured to reduce aberration of detection at the first or second
emissive component. The imaging system further includes a radiation
source configured to direct excitation radiation towards the first
and second emissive components. In addition, the imaging system
includes detection optics configured to capture emitted radiation
returned from the first and second emissive components via the
optical train. Further, the imaging system includes a detector for
detecting the captured radiation.
DRAWINGS
[0008] FIG. 1 is a diagrammatical overview for a biological sample
imaging system in accordance with the present invention;
[0009] FIG. 2 is a diagrammatical perspective view of an exemplary
radiation line directed toward a surface of a support structure to
semi-confocally irradiate biological sites, and to semi-confocally
return radiation to a detector in accordance with the present
invention;
[0010] FIG. 3 is a sectional view of an exemplary support structure
with excitation radiation directed at two surfaces of the support
structure in accordance with the present invention;
[0011] FIG. 4 is a diagrammatical perspective view of an exemplary
support structure having an array of biological component sites in
a spatially ordered pattern in accordance with the present
invention;
[0012] FIG. 5 is a diagrammatical perspective view of an exemplary
support structure having biological component sites in a random
spatial distribution in accordance with the present invention;
[0013] FIG. 6 is a sectional view of an exemplary support structure
with excitation radiation directed at multiple surfaces of the
support structure in accordance with the present invention;
[0014] FIG. 7 illustrates exemplary dimensions between the
objective and the support structure in accordance with the present
invention;
[0015] FIG. 8 is an exemplary chart of spherical aberration vs.
thickness of the upper plate of the support structure of FIG. 7 in
accordance with the present invention;
[0016] FIG. 9A illustrates exemplary images expected for first and
second surfaces of a support structure when obtained through an
upper surface thickness of 300 microns (plus 100 microns of fluid)
without corrective optics, where the imaging system is optimized
for the second surface;
[0017] FIG. 9B illustrates exemplary images expected for first and
second surfaces of a support structure when obtained through an
upper surface thickness of 340 microns (plus 100 microns of fluid)
without corrective optics;
[0018] FIG. 10A illustrates an exemplary objective imaging the
second surface without the assistance of a compensator in
accordance with the present invention;
[0019] FIG. 10B illustrates an exemplary objective imaging the
first surface with the assistance of a compensator in accordance
with the present invention;
[0020] FIG. 11 is an exemplary compensator design, incorporating a
first objective and a second objective which may replace the first
objective in the optical train in accordance with the present
invention;
[0021] FIG. 12 is another exemplary compensator design,
incorporating a corrective device which may be inserted between the
objective and the support structure in accordance with the present
invention;
[0022] FIG. 13 is another exemplary compensator design,
incorporating a correction collar in accordance with the present
invention;
[0023] FIG. 14 is another exemplary compensator design,
incorporating an infinite space compensator in accordance with the
present invention;
[0024] FIG. 15 is a perspective view of an exemplary flow cell
assembly using patterned adhesives to form channel characteristics
in accordance with the present invention;
[0025] FIG. 16 is a perspective view of another exemplary flow cell
assembly using patterned adhesives to form channel characteristics
in accordance with the present invention;
[0026] FIG. 17 is a process flow diagram of an exemplary method of
assembling flow cells using patterned adhesives to form channel
characteristics in accordance with the present invention;
[0027] FIG. 18 is a diagrammatical view of a biological sample
imaging system with one radiation source and dual detectors
configured to sequentially scan multiple surfaces of the support
structure in accordance with the present invention;
[0028] FIG. 19 is a diagrammatical view of a biological sample
imaging system with dual radiation sources and dual detectors
configured to sequentially scan multiple surfaces of the support
structure in accordance with the present invention;
[0029] FIG. 20 is a diagrammatical view of a biological sample
imaging system with dual radiation sources and dual detectors
configured to simultaneously scan multiple surfaces of the support
structure using focusing lenses along the excitation path in
accordance with the present invention;
[0030] FIG. 21 is a diagrammatical view of a biological sample
imaging system with dual radiation sources and dual detectors
configured to simultaneously scan multiple surfaces of the support
structure using focusing lenses along the excitation and emission
paths in accordance with the present invention;
[0031] FIG. 22 is a diagrammatical view of a biological sample
imaging system with multiple radiation sources and multiple
detectors configured to simultaneously scan multiple surfaces of
the support structure using focusing lenses along the excitation
and emission paths in accordance with the present invention;
[0032] FIG. 23 is a diagrammatical overview for a TIR biological
sample imaging system in accordance with the present invention;
[0033] FIG. 24 is a sectional view of an exemplary support
structure, prism, and lens objective for use with TIR imaging of a
bottom surface of a flow lane in accordance with the present
invention;
[0034] FIG. 25 is a sectional view of an exemplary support
structure, prism, and lens objective for use with TIR imaging of a
top surface of a flow lane in accordance with the present
invention;
[0035] FIG. 26 is a sectional view of another exemplary support
structure, prism, and lens objective for use with TIR imaging of a
top surface of a flow lane in accordance with the present
invention; and
[0036] FIG. 27 is a sectional view of an exemplary support
structure being heated on both top and bottom surfaces in
accordance with the present invention.
DETAILED DESCRIPTION
[0037] Turning now to the drawings, and referring first to FIG. 1,
a biological sample imaging system 10 is illustrated
diagrammatically. The biological sample imaging system 10 is
capable of imaging multiple biological components 12, 14 within a
support structure 16. For instance, in the illustrated embodiment,
a first biological component 12 may be present on a first surface
18 of the support structure 16 while a second biological component
14 may be present on a second surface 20 of the support structure.
The support structure 16 may, for instance, be a flow cell with an
array of biological components 12, 14 on the interior surfaces 18,
20 which generally mutually face each other and through which
reagents, flushes, and other fluids may be introduced, such as for
binding nucleotides or other molecules to the sites of biological
components 12, 14. The support structure 16 may be manufactured in
conjunction with the present techniques or the support structure 16
may be purchased or otherwise obtained from a separate entity.
Fluorescent tags on the molecules that bind to the components may,
for instance, include dyes that fluoresce when excited by
appropriate excitation radiation. Assay methods that include the
use of fluorescent tags and that can be used in an apparatus or
method set forth herein include those set forth elsewhere herein
such as genotyping assays, gene expression analysis, methylation
analysis, or nucleic acid sequencing analysis.
[0038] Those skilled in the art will recognize that a flow cell or
other support structure may be used with any of a variety of arrays
known in the art to achieve similar results. Furthermore, known
methods for making arrays can be used, and if appropriate, modified
in accordance with the teaching set forth herein in order to create
a flow cell or other support structure having multiple surfaces
useful in the detection methods set forth herein. Such arrays may
be formed by disposing the biological components of samples
randomly or in predefined patterns on the surfaces of the support
by any known technique. In a particular embodiment, clustered
arrays of nucleic acid colonies can be prepared as described in
U.S. Pat. No. 7,115,400; U.S. Patent Application Publication No.
2005/0100900; PCT Publication No. WO 00/18957; or PCT Publication
No. WO 98/44151, each of which is hereby incorporated by reference.
Such methods are known as bridge amplification or solid-phase
amplification and are particularly useful for sequencing
applications.
[0039] Other exemplary random arrays, and methods for their
construction, that can be used in the invention include, without
limitation, those in which beads are associated with a solid
support, examples of which are described in U.S. Pat. Nos.
6,355,431; 6,327,410; and U.S. Pat. No. 6,770,441; U.S. Patent
Application Publication Nos. 2004/0185483 and US 2002/0102578; and
PCT Publication No. WO 00/63437, each of which is hereby
incorporated by reference. Beads can be located at discrete
locations, such as wells, on a solid-phase support, whereby each
location accommodates a single bead.
[0040] Any of a variety of other arrays known in the art or methods
for fabricating such arrays can be used in the present invention.
Commercially available microarrays that can be used include, for
example, an Affymetrix.RTM. GeneChip.RTM. microarray or other
microarray synthesized in accordance with techniques sometimes
referred to as VLSIPS.TM. (Very Large Scale Immobilized Polymer
Synthesis) technologies as described, for example, in U.S. Pat.
Nos. 5,324,633; 5,744,305; 5,451,683; 5,482,867; 5,491,074;
5,624,711; 5,795,716; 5,831,070; 5,856,101; 5,858,659; 5,874,219;
5,968,740; 5,974,164; 5,981,185; 5,981,956; 6,025,601; 6,033,860;
6,090,555; 6,136,269; 6,022,963; 6,083,697; 6,291,183; 6,309,831;
6,416,949; 6,428,752; and 6,482,591, each of which is hereby
incorporated by reference. A spotted microarray can also be used in
a method of the invention. An exemplary spotted microarray is a
CodeLink.TM. Array available from Amersham Biosciences. Another
microarray that is useful in the invention is one that is
manufactured using inkjet printing methods such as SurePrint.TM.
Technology available from Agilent Technologies.
[0041] Sites or features of an array are typically discrete, being
separated with spaces between each other. The size of the sites
and/or spacing between the sites can vary such that arrays can be
high density, medium density, or lower density. High density arrays
are characterized as having sites separated by less than about 15
.mu.m. Medium density arrays have sites separated by about 15 to 30
.mu.m, while low density arrays have sites separated by greater
than 30 .mu.m. An array useful in the invention can have sites that
are separated by less than 100 .mu.m, 50 .mu.m, 10 .mu.m, 5 .mu.m,
1 .mu.m or 0.5 .mu.m. An apparatus or method of the invention can
be used to image an array at a resolution sufficient to distinguish
sites at the above densities or density ranges.
[0042] As exemplified herein, a surface used in an apparatus or
method of the invention is typically a manufactured surface. It is
also possible to use a natural surface or a surface of a natural
support structure; however the invention can be carried out in
embodiments where the surface is not a natural material or a
surface of a natural support structure. Accordingly, components of
biological samples can be removed from their native environment and
attached to a manufactured surface.
[0043] Any of a variety of biological components can be present on
a surface for use in the invention. Exemplary components include,
without limitation, nucleic acids such as DNA or RNA, proteins such
as enzymes or receptors, polypeptides, nucleotides, amino acids,
saccharides, cofactors, metabolites or derivatives of these natural
components. Although the apparatus and methods of the invention are
exemplified herein with respect to components of biological
samples, it will be understood that other samples or components can
be used as well. For example, synthetic samples can be used such as
combinatorial libraries, or libraries of compounds having species
known or suspected of having a desired structure or function. Thus,
the apparatus or methods can be used to synthesize a collection of
compounds and/or screen a collection of compounds for a desired
structure or function.
[0044] Returning to the exemplary system of FIG. 1, the biological
sample imaging system 10 may include at least a first radiation
source 22 but may also include a second radiation source 24 (or
additional sources). The radiation sources 22, 24 may be lasers
operating at different wavelengths. The selection of the
wavelengths for the lasers will typically depend upon the
fluorescence properties of the dyes used to image the component
sites. Multiple different wavelengths of the lasers used may permit
differentiation of the dyes at the various sites within the support
structure 16, and imaging may proceed by successive acquisition of
a series of images to enable identification of the molecules at the
component sites in accordance with image processing and reading
logic generally known in the art. Other radiation sources known in
the art can be used including, for example, an arc lamp or quartz
halogen lamp. Particularly useful radiation sources are those that
produce electromagnetic radiation in the ultraviolet (UV) range
(about 200 to 390 nm), visible (VIS) range (about 390 to 770 nm),
infrared (IR) range (about 0.77 to 25 microns), or other range of
the electromagnetic spectrum.
[0045] For ease of description, embodiments utilizing
fluorescence-based detection are used as examples. However, it will
be understood that other detection methods can be used in
connection with the apparatus and methods set forth herein. For
example, a variety of different emission types can be detected such
as fluorescence, luminescence, or chemiluminescence. Accordingly,
components to be detected can be labeled with compounds or moieties
that are fluorescent, luminescent, or chemiluminescent. Signals
other than optical signals can also be detected from multiple
surfaces using apparatus and methods that are analogous to those
exemplified herein with the exception of being modified to
accommodate the particular physical properties of the signal to be
detected.
[0046] Output from the radiation sources 22, 24 may be directed
through conditioning optics 26, 28 for filtering and shaping of the
beams. For example, in a presently contemplated embodiment, the
conditioning optics 26, 28 may generate a generally linear beam of
radiation, and combine beams from multiple lasers, for example, as
described in U.S. Pat. No. 7,329,860. The laser modules can
additionally include a measuring component that records the power
of each laser. The measurement of power may be used as a feedback
mechanism to control the length of time an image is recorded in
order to obtain uniform exposure, and therefore more readily
comparable signals.
[0047] After passing through the conditioning optics 26, 28, the
beams may be directed toward directing optics 30 which redirect the
beams from the radiation sources 22, 24 toward focusing optics 32.
The directing optics 30 may include a dichroic minor configured to
redirect the beams toward the focusing optics 32 while also
allowing certain wavelengths of a retrobeam to pass therethrough.
The focusing optics 32 may confocally direct radiation to one or
more surfaces 18, 20 of the support structure 16 upon which
individual biological components 12, 14 are located. For instance,
the focusing optics 32 may include a microscope objective that
confocally directs and concentrates the radiation sources 22, 24
along a line to a surface 18, 20 of the support structure 16.
[0048] Biological component sites on the support structure 16 may
fluoresce at particular wavelengths in response to an excitation
beam and thereby return radiation for imaging. For instance, the
fluorescent components may be generated by fluorescently tagged
nucleic acids that hybridize to complementary molecules of the
components or to fluorescently tagged nucleotides that are
incorporated into an oligonucleotide using a polymerase. As noted
above, the fluorescent properties of these components may be
changed through the introduction of reagents into the support
structure 16 (e.g., by cleaving the dye from the molecule, blocking
attachment of additional molecules, adding a quenching reagent,
adding an acceptor of energy transfer, and so forth). As will be
appreciated by those skilled in the art, the wavelength at which
the dyes of the sample are excited and the wavelength at which they
fluoresce will depend upon the absorption and emission spectra of
the specific dyes. Such returned radiation may propagate back
through the directing optics 30. This retrobeam may generally be
directed toward detection optics 34 which may filter the beam such
as to separate different wavelengths within the retrobeam, and
direct the retrobeam toward at least one detector 36.
[0049] The detector 36 may be based upon any suitable technology,
and may be, for example, a charged coupled device (CCD) sensor that
generates pixilated image data based upon photons impacting
locations in the device. However, it will be understood that any of
a variety of other detectors may also be used including, but not
limited to, a detector array configured for time delay integration
(TDI) operation, a complementary metal oxide semiconductor (CMOS)
detector, an avalanche photodiode (APD) detector, a Geiger-mode
photon counter, or any other suitable detector. TDI mode detection
can be coupled with line scanning as described in U.S. Pat. No.
7,329,860.
[0050] The detector 36 may generate image data, for example, at a
resolution between 0.1 and 50 microns, which is then forwarded to a
control/processing system 38. In general, the control/processing
system 38 may perform various operations, such as analog-to-digital
conversion, scaling, filtering, and association of the data in
multiple frames to appropriately and accurately image multiple
sites at specific locations on a sample. The control/processing
system 38 may store the image data and may ultimately forward the
image data to a post-processing system (not shown) where the data
are analyzed. Depending upon the types of sample, the reagents
used, and the processing performed, a number of different uses may
be made of the image data. For example, nucleotide sequence data
can be derived from the image data, or the data may be employed to
determine the presence of a particular gene, characterize one or
more molecules at the component sites, and so forth. The operation
of the various components illustrated in FIG. 1 may also be
coordinated with the control/processing system 38. In a practical
application, the control/processing system 38 may include hardware,
firmware, and software designed to control operation of the
radiation sources 22, 24, movement and focusing of the focusing
optics 32, a translation system 40, and the detection optics 34,
and acquisition and processing of signals from the detector 36. The
control/processing system 38 may thus store processed data and
further process the data for generating a reconstructed image of
irradiated sites that fluoresce within the support structure 16.
The image data may be analyzed by the system itself, or may be
stored for analysis by other systems and at different times
subsequent to imaging.
[0051] The support structure 16 may be supported on a translation
system 40 which allows for focusing and movement of the support
structure 16 before and during imaging. The stage may be configured
to move the support structure 16, thereby changing the relative
positions of the radiation sources 22, 24 and detector 36 with
respect to the surface bound biological components for progressive
scanning. Movement of the translation system 40 can be in one or
more dimensions including, for example, one or both of the
dimensions that are orthogonal to the direction of propagation for
the excitation radiation line, typically denoted as the X and Y
dimensions. In particular embodiments, the translation system 40
may be configured to move in a direction perpendicular to the scan
axis for a detector array. A translation system 40 useful in the
present invention may be further configured for movement in the
dimension along which the excitation radiation line propagates,
typically denoted as the Z dimension. Movement in the Z dimension
can also be useful for focusing.
[0052] FIG. 2 is a diagrammatical representation of an exemplary
semi-confocal line scanning approach to imaging the support
structure 16. In the illustrated embodiment, the support structure
16 includes an upper plate 42 and a lower plate 44 with an internal
volume 46 between the upper and lower plates 42, 44. The upper and
lower plates 42, 44 may be made of any of a variety of materials
but may preferably be made of a substrate material that is
substantially transparent at the wavelengths of the excitation
radiation and the fluoresced retrobeam, allowing for the passage of
excitation radiation and returned fluorescent emissions without
significant loss of signal quality. Moreover, when used in
epifluorescent imaging arrangements as shown, one of the surfaces
through which the radiation traverses may be substantially
transparent at the relevant wavelengths, while the other (which is
not traversed by radiation) may be less transparent, translucent,
or even opaque or reflective. The upper and lower plates 42, 44 may
both contain biological components 12, 14 on their respective,
inwardly facing surfaces 18, 20. As discussed above, the internal
volume 46 may, for instance, include one or more internal passages
of a flow cell though which reagent fluids may flow.
[0053] The support structure 16 may be irradiated by excitation
radiation 48 along a radiation line 50. The radiation line 50 may
be formed by the excitation radiation 48 from the radiation sources
22, 24, directed by the directing optics 30 through the focusing
optics 32. The radiation sources 22, 24 may generate beams that are
processed and shaped to provide a linear cross section or radiation
line including a plurality of wavelengths of radiation used to
cause fluorescence at correspondingly different wavelengths from
the biological components 12, 14, depending upon the particular
dyes used. The focusing optics 32 may then semi-confocally direct
the excitation radiation 48 toward the first surface 18 of the
support structure 16 to irradiate sites of biological component 12
along the radiation line 50. In addition, the support structure 16,
the directing optics 30, the focusing optics 32, or some
combination thereof, may be slowly translated such that the
resulting radiation line 50 progressively irradiates the component
as indicated by the arrow 52. This translation results in
successive scanning of regions 54 which allow for the gradual
irradiation of the entire first surface 18 of the support structure
16. As will be discussed in more detail below, the same process may
also be used to gradually irradiate the second surface 20 of the
support structure 16. Indeed, the process may be used for multiple
surfaces within the support structure 16.
[0054] Exemplary methods and apparatus for line scanning are
described in U.S. Pat. No. 7,329,860, which is incorporated herein
by reference, and which describes a line scanning apparatus having
a detector array configured to achieve confocality in the scanning
axis by restricting the scan-axis dimension of the detector array.
More specifically, the scanning device can be configured such that
the detector array has rectangular dimensions such that the shorter
dimension of the detector is in the scan-axis dimension and imaging
optics are placed to direct a rectangular image of a sample region
to the detector array such that the shorter dimension of the image
is also in the scan-axis dimension. In this way, semi-confocality
can be achieved since confocality occurs in a single axis (i.e. the
scan axis). Thus, detection is specific for features on the surface
of a substrate, thereby rejecting signals that may arise from the
solution around the feature. The apparatus and methods described in
U.S. Pat. No. 7,329,860 can be modified such that two or more
surfaces of a support are scanned in accordance with the
description herein.
[0055] Detection apparatus and methods other than line scanning can
also be used. For example, point scanning can be used as described
below or in U.S. Pat. No. 5,646,411, which is incorporated herein
by reference. Wide angle area detection can be used with or without
scanning motion. As set forth in further detail elsewhere herein,
TIR methods can also be used.
[0056] As illustrated generally in FIG. 2, the radiation line 50
used to image the sites of biological components 12, 14, in
accordance with the present invention, may be a continuous or
discontinuous line. As such, some embodiments of the present
invention may include a discontinuous line made up of a plurality
of confocally or semi-confocally directed beams of radiation which
nevertheless irradiate a plurality of points along the radiation
line 50. These discontinuous beams may be created by one or more
sources that are positioned or scanned to provide the excitation
radiation 48. These beams, as before, may be confocally or
semi-confocally directed toward the first or second surfaces 18, 20
of the support structure 16 to irradiate sites of biological
component 12, 14. As with the continuous semi-confocal line
scanning described above, the support structure 16, the directing
optics 30, the focusing optics 32, or some combination thereof, may
be advanced slowly as indicated by arrow 52 to irradiate successive
scanned regions 54 along the first or second surfaces 18, 20 of the
support structure 16, and thereby successive regions of the sites
of biological components 12, 14.
[0057] It should be noted that the system will typically form and
direct excitation and returned radiation simultaneously for
imaging. In some embodiments, confocal point scanning may be used
such that the optical system directs an excitation point or spot
across a biological component by scanning the excitation beam
through an objective lens. The detection system images the emission
from the excited point on the detector without "descanning" the
retrobeam. This occurs since the retrobeam is collected by the
objective lens and is split off the excitation beam optical path
before returning back through the scan means. Therefore, the
retrobeam will appear on the detector 36 at different points
depending on the field angle of the original excitation spot in the
objective lens. The image of the excitation point, at the detector
36, will appear in the shape of a line as the excitation point is
scanned across the sample. This architecture is useful, for
example, if the scan means cannot for some reason accept the
retrobeam from the sample. Examples are holographic and acoustic
optic scan means that are able to scan a beam at very high speeds
but utilize diffraction to create the scan. Therefore, the scan
properties are a function of wavelength. The retrobeam of emitted
radiation is at a different wavelength from the excitation beam.
Alternatively or additionally, emission signals may be collected
sequentially following sequential excitation at different
wavelengths.
[0058] In particular embodiments, an apparatus or method of the
invention can detect features on a surface at a rate of at least
about 0.01 mm.sup.2/sec. Depending upon the particular application
of the invention, faster rates can also be used including, for
example, in terms of the area scanned or otherwise detected, a rate
of at least about 0.02 mm.sup.2/sec, 0.05 mm.sup.2/sec, 0.1
mm.sup.2/sec, 1 mm.sup.2/sec, 1.5 mm.sup.2/sec, 5 mm.sup.2/sec, 10
mm.sup.2/sec, 50 mm.sup.2/sec, 100 mm.sup.2/sec, or faster. If
desired, for example, to reduce noise, the detection rate can have
an upper limit of about 0.05 mm.sup.2/sec, 0.1 mm.sup.2/sec, 1
mm.sup.2/sec, 1.5 mm.sup.2/sec, 5 mm.sup.2/sec, 10 mm.sup.2/sec, 50
mm.sup.2/sec, or 100 mm.sup.2/sec.
[0059] In some instances, the support structure 16 may be used in
such a way that biological components are expected to be present on
only one surface. However, in many instances, biological material
is present on multiple surfaces within the support structure 16.
For instance, FIG. 3 illustrates a typical support structure 16
where biological material has attached to the first surface 18 as
well as to the second surface 20. In the illustrated embodiment, an
attachment layer 56 has formed on both the first surface 18 and the
second surface 20 of the support structure 16. A first excitation
radiation 58 source may be used to irradiate one of many sites of
biological component 12 on the first surface 18 of the support
structure 16 and return a first fluorescent emission 60 from the
irradiated biological component 12. Simultaneously or sequentially,
a second source of excitation radiation 62 may be used to irradiate
one of many sites of biological component 14 on the second surface
20 of the support structure 16, and return a second fluorescent
emission 64 from the irradiated biological component 14.
[0060] Although the embodiment exemplified in FIG. 3 shows
excitation from source 58 and source 62 coming from the same side
of the support structure 16, it will be understood that the optical
system can be configured to impinge on the surfaces from opposite
sides of the support structure 16. Taking FIG. 3 as an example,
upper surface 18 can be irradiated from excitation source 58 as
shown and the lower surface 20 can be irradiated from below.
Similarly, emission can be detected from one or more sides of a
support structure. In particular embodiments, different sides of
the support structure 16 can be excited from the same radiation
source by first irradiating one side and then flipping the support
structure to bring another side into position for excitation by the
radiation source.
[0061] The distribution of biological components 12, 14 may follow
many different patterns. For instance, FIG. 4 illustrates a support
structure 16 where the biological components 12, 14 at sites or
features on the first and second surfaces 18, 20 are distributed
evenly in a spatially ordered pattern 66 of biological component
sites 68. For example, certain types of microarrays may be used
where the location of individual biological component sites 68 may
be in a regular spatial pattern. The pattern can include sites at
pre-defined locations. In contrast, in other types of biological
imaging arrays, biological components attach to surfaces at sites
that occur in random or statistically varying positions such that
imaging the microarray is used to determine the location of each of
the individual biological component features. Thus, the pattern of
features need not be pre-determined despite being the product of a
synthetic or manufacturing process.
[0062] For instance, FIG. 5 illustrates a support structure 16
where the sites on the first and second surfaces 18, 20 are located
in a random spatial distribution 70 of biological component sites
72. However, with both fixed arrays 66 and random distribution 70
of biological sample sites, imaging of multiple surfaces 18, 20 of
the support structure 16 may be possible. In addition, it should be
noted that in both instances, the biological components at the
individual sites may constitute either a population of identical
molecules or a random mix of different molecules. Furthermore, the
density of biological samples may vary and may be at least 1,000
sites per square millimeter.
[0063] The present techniques accommodate such varied physical
arrangements of the multiple surfaces within the support structure
16, as well as the varied disposition of the sites within
components on the surfaces. As discussed above with reference to
FIGS. 2 and 3, in the embodiments with a support structure 16
having a first surface 18 and a second surface 20, a first source
of excitation radiation 58 may irradiate sites of biological
component 12 on the first surface 18, and return a first
fluorescent emission 60, while a second source of excitation
radiation 62 may irradiate sites of biological component 14 on the
second surface 20 and return a second fluorescent emission 64
source, as illustrated in FIG. 3. Thus, components of the volume of
sample between two surfaces need not be detected and can be
rejected. Selective detection of a surface of a support structure
provides preferential detection of the surface compared to the
volume of the support structure adjacent the surface and compared
to one or more other surfaces of the support structure.
[0064] In more complex configurations, it may be useful to
irradiate more than two surfaces. For instance, FIG. 6 illustrates
a support structure 16 having N number of plates including a first
plate 42, a second plate 44, . . . , an N-2 plate 74, an N-1 plate
76, and an N plate 78. These plates define M number of surfaces
including a first surface 18, a second surface 20, . . . , an M-3
surface 80, an M-2 surface 82, an M-1 surface 84, and an M surface
86. In the illustrated embodiment, not only the first surface 18
and the second surface 20 of the support structure 16 may be
irradiated but, rather, all M number of surfaces may be irradiated.
For instance, a source of excitation radiation 88 may be used to
irradiate biological component sites on the M.sup.th surface 86 of
the support structure 16 and return a fluorescent emission 90 from
the irradiated biological component. For support structures having
a plurality of surfaces it may be desirable to excite upper layers
from the top and lower layers from the bottom to reduce
photobleaching. Thus, components on layers that are closer to a
first exterior side of a support structure can be irradiated from
the first side, whereas irradiation from the opposite exterior side
can be used to excite components present on layers that are closer
to the opposite exterior side.
[0065] FIG. 7 illustrates an objective 92 through which radiation
from emissive biological components 12, 14 on first and second
surfaces 18, 20, respectively, of the support structure 16 may be
detected. The objective 92 may be one of the components of the
focusing optics 32 described above. Although not drawn to scale,
FIG. 7 illustrates exemplary dimensions between the objective 92
and the support structure 16. For instance, the objective 92 may
typically be spaced approximately 600 or more microns from the
upper plate 42 of the support structure 16. The biological sample
imaging system 10 may be configured to detect emitted radiation
from biological components 12 on the first surface 18 through 300
microns of the upper plate 42 which may, for instance, be made of
glass and may have a refractive index N.sub.d of 1.472. In
addition, the biological sample imaging system 10 may also be
configured to detect emitted radiation from biological components
14 on the second surface 20 through 300 microns of the upper plate
42 plus 100 microns of the fluid within the internal volume 46 of
the support structure 46.
[0066] In certain embodiments, the objective 92 may be designed for
diffraction-limited focusing and imaging on only one of the first
or second surfaces 18, 20 of the support structure 16. For example
throughout the present description of FIGS. 7 through 14, the
objective 92 may be designed for pre-compensation of the 300
microns of the upper plate 42 plus the 100 micron read buffer of
the fluid within the internal volume 46 of the support structure
16. In such a scenario, diffraction-limited performance may only be
possible on the second surface 20. Furthermore, the spherical
aberration introduced by the 100 micron read buffer may severely
impact the imaging quality when imaging from the first surface 18.
However, reducing the lane thickness of the internal volume 46 of
the support structure 16 might increase the amount of
surface-to-surface "crosstalk." Therefore, perhaps the most
appropriate solution is to correct the aberration. As such, it may
be necessary to use a compensator capable of achieving
diffraction-limited imaging performance on both the first and
second surfaces 18, 20 of the support structure 16.
[0067] It should be noted that the need for a compensator may be
more pronounced when using objectives 92 with high numerical
aperture (NA) values. Exemplary high NA ranges for which the
invention is particularly useful include NA values of at least
about 0.6. For example, the NA may be at least about 0.65, 0.7,
0.75, 0.8, 0.85, 0.9, 0.95, or higher. Those skilled in the art
will appreciate that NA, being dependent upon the index of
refraction of the medium in which the lens is working, may be
higher including, for example, up to 1.0 for air, 1.33 for pure
water, or higher for other media such as oils. The compensator may
also find use in objectives having lower NA values than the
examples listed above. In general, the NA value of an objective 92
is a measure of the breadth of angles for which the objective 92
may receive light. The higher the NA value, the more light that may
be collected by the objective 92 for a given fixed magnification.
This is because the collection efficiency and the resolution
increase. As a result, multiple objects may be distinguished more
readily when using objectives 92 with higher NA values because a
higher feature density may be possible. Therefore, in general, a
higher NA value for the objective 92 may be beneficial for imaging.
However, as the NA value increases, its sensitivity to focusing and
imaging-through media thickness variation also increases. In other
words, lower NA objectives 92 have longer depth of field and are
generally not as sensitive to changes in imaging-through media
thickness.
[0068] FIG. 8 is an exemplary chart 94 of spherical aberration (in
waves) vs. thickness (in microns) of the upper plate 42 of the
support structure 16 of FIG. 7 in accordance with the present
invention. Specifically, the upper line 96 of the graph depicts the
amount of spherical aberration of an image taken from biological
components 12 on the first surface 18 of the support structure 16
while the lower line 98 of the graph depicts the amount of
spherical aberration of an image taken from biological components
14 on the second surface 20 of the support structure 16. In the
illustrated embodiment, the spherical aberration generated by the
100 micron read buffer is around 4 waves, which is much higher than
the diffraction-limited performance requirement of less than 0.25
waves, for instance. As illustrated, at 300 microns (i.e. the
thickness of the upper plate 42), the spherical aberration for the
first surface 18 is around -13.2 waves (e.g., point 100) while the
spherical aberration for the second surface 20 is around -17.2
waves (e.g., point 102). FIG. 9A illustrates exemplary images
expected for the first and second surfaces 18, 20 of the support
structure 16 corresponding to the thickness of the upper plate 42
(i.e., 300 microns) in accordance with the present invention, where
the imaging system is optimized for the second surface 20
(pre-compensated for -17.2 waves). As shown, the imaging system is
capable of providing high image quality on the second surface 20
since, according to the present scenario, it was designed to do so.
However, the images taken for the first surface 18 contain
aberrations.
[0069] To balance out the spherical aberration, it is beneficial to
introduce an additional thickness (e.g., by introducing an
additional coverslip) between the objective 92 and the support
structure 16. For instance, returning now to FIG. 8, if an
additional thickness of approximately 40 microns were to be
introduced between the objective 92 and the first and second
surfaces 18, 20 of support structure 16, the difference between the
spherical aberrations at the design thickness (i.e., 300 micron
upper plate plus 100 microns of fluid) may be split such that the
image produced for both the first and second surfaces 18, 20 may
have similar quality. For instance, as illustrated, at 340 microns
(i.e. the thickness of the upper plate 42 plus an additional 40
micron thickness), the spherical aberration for the first surface
18 is around -15.2 waves (e.g., point 104) while the spherical
aberration for the second surface 20 is around -19.2 waves (e.g.,
point 106), splitting the difference of -17.2 waves (e.g., point
108) which may be characterized as the design point for the
objective 92. FIG. 9B illustrates exemplary images expected for the
first and second surfaces 18, 20 of the support structure 16
corresponding to the thickness of the upper plate 42 plus an
additional thickness (i.e., 300 microns plus 40 microns) in
accordance with the present invention, illustrating how the
additional thickness may allow for balance between images taken for
the first and second surfaces 18, 20 of the support structure
16.
[0070] However, merely introducing an additional thickness between
the objective 92 and the support structure 16 may not be desired
for all uses of the imaging system set forth herein. For instance,
as illustrated in FIGS. 9A and 9B, by simply introducing the
additional 40 micron thickness between the objective 92 and the
support structure 16, images from both the first and second
surfaces 18, 20 may still experience residual aberration from the
design point 108 of the objective 92. Therefore, a more precise
solution may be to only introduce the additional thickness when
detecting radiation from biological components 12 on the first
surface 18 of the support structure 16. In such a scenario, the
spherical aberration corresponding to the design point 108 of the
objective 92 may generally be achieved for both the first and
second surfaces 18, 20. It should be noted that the particular
dimensions and measurements (e.g., thicknesses, spherical
aberration values, and so forth) described with respect to FIGS. 9A
and 9B are merely intended to be exemplary of the manner in which
the present invention functions. As such, these dimensions and
measurements are not intended to be limiting. Indeed, the
particular geometries and resulting measurement values may vary
between implementations.
[0071] For example, FIG. 10A illustrates an exemplary objective 92
imaging the second surface 20 of the support structure 16 without
the assistance of a compensator 110 in accordance with the present
invention. Without the compensator 110, the objective 92 may focus
and detect images from the second surface 20 of the support
structure 16 according to its design and experiencing the design
spherical aberration. However, FIG. 10B illustrates an exemplary
objective 92 imaging the first surface 20 of the support structure
16 with the assistance of a compensator 110 in accordance with the
present invention. By using the compensator 110 (e.g., similar to
the additional 40 micron thickness described above with respect to
FIGS. 8 and 9), the objective 92 may focus and detect images from
the first surface 18 of the support structure 16 under similar
conditions to that of its design point for the second surface 20 of
the support structure 16. Therefore, by detecting images for the
second surface 20 without the compensator 110 and detecting images
for the first surface 18 with the compensator 110, the objective 92
may be capable of detecting images on both surfaces with
diffraction-limited performance similar to the design of the
objective 92.
[0072] The chromatic shift curve may be limited to wavelength
ranges of between 530 nm to 780 nm. Chromatic shifts of different
color wavelength bands may be compensated for by focusing the
focusing optics 32 in each band. The compensator 110 should
preferably be "invisible" to the focusing optics 32. In other
words, the compensator 110 should correct the spherical aberration
difference of the read buffer but should maintain the chromatic
shift curve in the wavelength range of 530-780 nm. More
specifically, the chromatic shift relationships among the peak
wavelengths of 560 nm, 610 nm, 687 nm, and 720 nm should be
maintained. In addition, other specifications, including NA, field
curvature, field distortion, detection magnification, and so forth,
should also be maintained. Furthermore, the compensator 110 package
should be relatively small (e.g., no more than 10 mm of total
thickness). Moreover, insensitivity to positioning error of the
compensator 110 may be preferred.
[0073] Several various designs may be implemented to introduce the
corrective optics of the compensator 110 into the optical train of
the imaging optics of the biological sample imaging system 10. For
example, FIG. 11 is an exemplary compensator 110 design,
incorporating a first objective 92 and a second objective 112 which
may replace the first objective 92 in the optical train in
accordance with the present invention. In the illustrated
embodiment, each respective objective 92, 112 may contain the
optics required to image respective surfaces, such as the first and
second surfaces 18, 20 of the support structure 16. For instance,
the first objective 92 may contain the imaging optics necessary to
focus on and image emissive biological components 14 on the second
surface 20 of the support structure 16 while the second objective
112 may contain the imaging optics plus the corrective optics
necessary to focus on and image emissive biological components 12
on the first surface 18 of the support structure 16. In operation,
the first objective 92 may detect images from the second surface 20
of the support structure 16. The first objective 92 may be replaced
by the second objective 112 in the optical train, at which point
the second objective 112 may detect images from the first surface
18 of the support structure 16. An advantage of the embodiment
illustrated in FIG. 11 is that the optics may be decoupled and may
operate independently. However, a disadvantage in some situations
is that having two entirely separate objectives 92, 112 may not be
cost-effective since certain components may be duplicated for each
objective 92, 112. Furthermore, in embodiments where multiple
images of an object are obtained, the use of two objectives may
increase the computational resources required for registration
between images. In particular embodiments, imaging of both surfaces
may occur through the same objective to provide particular
advantages as set forth below. In other words, the first objective
92 need not be removed or replaced with the second objective 112
for imaging of the different surfaces.
[0074] FIG. 12 is another exemplary compensator 110 design,
incorporating a corrective device 114 which may be inserted between
the objective 92 and the support structure 16 in accordance with
the present invention. The corrective device 114 may, for instance,
be a coverslip or other thin layer of glass. As illustrated, the
corrective device 114 may simply be inserted into and removed from
the optical path between the objective 92 and the support structure
16 depending on the particular surface 16 being imaged. For
instance, the corrective device 114 may be removed from the optical
path when the objective 92 is used to focus on and image emissive
biological components 14 on the second surface 20 of the support
structure 16. Conversely, the corrective device 114 may be inserted
into the optical path when the objective 92 is used to focus on and
image emissive biological components 12 on the first surface 18 of
the support structure 16. An advantage of the embodiment
illustrated in FIG. 12 is that it is relatively straightforward.
The required additional compensator thickness may simply be
inserted into the optical path. Typically, the corrective device
114 may be placed such that it does not physically contact the
support structure 16 or the objective 92.
[0075] FIG. 13 is another exemplary compensator 110 design,
incorporating a correction collar 116 in accordance with the
present invention. In the illustrated embodiment, the correction
collar 116 may be adjusted between binary states. For instance, the
first state 118 may correspond to the situation where the objective
92 is focused on and detecting images from the second surface 20 of
the support structure 16 while the second state 120 may correspond
to the situation where the objective 92 is focused on and detecting
images from the first surface of the support structure 16. As such,
when the correction collar 116 is in the first state 118, the
imaging optics within the objective 92 may not include the
corrective optics within the optical path. Conversely, when the
correction collar 116 is in the second state 120, the imaging
optics within the objective 92 may include the corrective optics
within the optical path. Although illustrated as consisting of
binary states 118, 120, the correction collar 116 may, in fact,
include multiple states. For instance, when more than two surfaces
of the support structure 16 are used for imaging, the correction
collar 116 may be configured to adjust between multiple states such
that the imaging and corrective optics vary for each respective
surface of the support structure 16. An advantage of the embodiment
illustrated in FIG. 13 is that it may be relatively easy to
operate. For instance, the correction collar 116 may simply be
adjusted between states whenever different surfaces of the support
structure 16 are being imaged.
[0076] FIG. 14 is another exemplary compensator 110 design,
incorporating an infinite space compensator 122 in accordance with
the present invention. This embodiment is somewhat similar to the
corrective device 114 embodiment of FIG. 12 in that the infinite
space compensator 122 may be inserted into and removed from the
optical path. However, a main difference between the embodiments is
that, in the embodiment of FIG. 14, there may be more space
available (e.g., up to 10 mm, as opposed to 600 microns in the
embodiment of FIG. 12) within which to insert the infinite space
compensator 122 into the optical path. Therefore, the embodiment of
FIG. 14 may allow for greater flexibility than the corrective
device 114 embodiment of FIG. 12.
[0077] In addition to the embodiments presented in FIGS. 11 through
14, there may be other compensator 110 designs which may prove
beneficial. For instance, a fluidic corrector may be inserted
between the objective 92 and the support structure 16. In this
fluidic corrector design, the fluidic corrector may be filled with
a fluid, which may effectively act as the compensator 110. The
optics may be configured such that the fluid matches the upper
surface of the support structure 16 and, in the absence of fluid
air, matches the bottom surface of support structure 16. This
design may prove beneficial in that it may make automation easier
since the fluid would simply be inserted into and extracted from
the fluidic corrector depending on which surface is imaged.
[0078] Regardless of the particular embodiment selected, all of the
embodiments disclosed herein are characterized by repeatability and
the ability to automate the use of the embodiments. These are
important considerations in that the embodiments allow for the
detection of images from biological components 12, 14 on multiple
surfaces 18, 20 of the support structure 16 in an automated
fashion. This may allow not only for increased imaging production
but may also allow for greater flexibility in switching between the
multiple surfaces, depending on the particular imaging needs.
[0079] As described in greater detail above, a support structure 16
useful in the apparatus or methods set forth herein can have two or
more surfaces upon which a biological component is attached. In
particular embodiments, the surface is a fabricated surface. Any of
a variety of surfaces known in the art can be used including, but
not limited to, those used for making arrays as set forth above.
Examples include, glass, silicon, polymeric structures, plastics,
and the like. Surfaces and flow cells that are particularly useful
are described in PCT Publication No. WO 2007/123744, which is
incorporated herein by reference. The surfaces of a support
structure can have the same or different properties. For example,
in the embodiment shown in FIG. 3, plate 42 can be transparent to
the excitation and emission wavelengths used in a detection method,
whereas plate 44 can optionally be transparent or opaque to the
excitation or emission wavelengths. Accordingly, the surfaces can
be made of the same material or the two or more surfaces can be
made of different materials.
[0080] A support structure having two or more surfaces can be
formed by adhering the surfaces to each other or to other supports.
For example, an adhesive material, such as epoxy resin, can be
dispensed in the form of a paste onto a planar substrate in a
pattern forming one or more channel characteristics of a flow cell.
An exemplary flow cell 124 is shown in FIG. 15. Utilizing a
programmable, automated adhesive dispenser, such as the
Millennium.RTM. M-2010 from Asymtek Corp., Carlsbad Calif., a
desired pattern of adhesive 126 can be designed and laid down onto
the surface of a planar lower substrate 128. The thickness of the
flow cell (and cross sectional height in the fluidic channels) can
be set by means of precision mechanical spacers 130 placed between
the lower substrate 128 and an upper substrate 132. Another
exemplary flow cell 134 is shown in FIG. 16. To create a
multi-layer cell, an interim transparent substrate layer 136,
shorter in length than the lower and upper substrate layers 128,
132 can be included. The shorter length allows fluidic access to
both/all layers from ports 138 passing through only one substrate.
This intermediate layer 136 bifurcates the flow cell cavity
horizontally and nearly doubles the available surface area for the
attachment of biologically interesting molecules.
[0081] An exemplary method 140 for fabricating such a flow cell is
shown in FIG. 17. A planar substrate acting as the structural base
of the cell is provided (block 142). Desired canalizing features of
the cell are designed, for example, using a computer assisted
design program (block 144). A pattern designed in this way can be
exported to a file compatible with driving an automatic adhesive
dispensing system (block 146). A program can be executed to
dispense the adhesive in the desired pattern onto the substrate
(block 148). Precision mechanical spacers can be placed onto the
base substrate before or after the adhesive is dispensed (block
150). A second transparent substrate can then be placed onto the
adhesive pattern, pressing downward until the lower surface is in
full contact with the mechanical spacers (block 152). A weight or
other force is applied to the top substrate to hold it in full
contact with the adhesive. The spacers will typically have a height
that is equivalent or slightly less than the height of the adhesive
layer such that bonding can occur without causing undesirable
aberrations in the shape of the canalized features. The steps for
adhering substrates may be repeated for any number of layers
desired. Optionally, the assembly can be heat treated, for example,
in an oven or exposed to UV light, depending upon the cure
requirements of the adhesive (block 154).
[0082] Another exemplary method for fabricating a flow cell is to
use an intermediate layer that is cut to a desired pattern in place
of an adhesive layer. A particularly useful material for the
intermediate layer is silicone. The silicone layer can be heat
bonded to the lower substrate 128 and upper substrate 132.
Exemplary methods utilizing Bisco Silicone HT 6135 as an
intermediate layer are described, for example, in Grover et al.,
Sensors and Actuators B 89:315-323 (2003).
[0083] Still further, FIG. 18 illustrates an embodiment utilizing
one radiation source and dual detectors. Radiation from the
radiation source 22 is directed by the directing optics 30 toward
the focusing optics 32. From the focusing optics 32, the excitation
radiation 58 irradiates a biological component 12 on a first
surface 18 of the support structure 16. The biological component 12
emits a fluorescent emission 60 back through the focusing optics 32
toward the directing optics 30. This retrobeam is allowed to pass
through the directing optics 30 to the detection optics 34 which,
in this illustrated embodiment, may include a wavelength filter 156
or some other device for separating the retrobeam, and first and
second color filters 158, 160 for achieving multiple color
channels. The wavelength filter 156 may split the retrobeam into
two beams with one beam directed toward the first detector 36 via
the first color filter 158 and the other beam directed toward a
second detector 162 via the second color filter 160. In this
manner, the biological sample imaging system 10 may sequentially
scan the first and second surfaces 18, 20, first scanning the first
surface 18 of the support structure 16 using the first excitation
radiation 58 from the radiation source 22 and the returned first
fluorescent emission 60 (as depicted in the left portion of FIG.
18), and next scanning the second surface 20 of the support
structure 16 using the second excitation radiation 62 from the same
radiation source 22 and the returned second fluorescent emission 64
(as depicted in the right portion of FIG. 18).
[0084] Alternatively, FIG. 19 illustrates an embodiment utilizing
dual radiation sources and dual detectors. Again, the two surfaces
18, 20 of the support structure 16 may be scanned sequentially.
However, in this embodiment, the first surface 18 of the support
structure 16 is first scanned using the first radiation source 22
which generates the first excitation radiation 58 and the first
fluorescent emission 60 (as depicted in the left portion of FIG.
19) and, the second surface 20 of the support structure 16 is
scanned using the second radiation source 24 which generates the
second excitation radiation 62 and the second fluorescent emission
64 (as depicted in the right portion of FIG. 19). This embodiment
may also be extended to use any number of detectors in order to
reduce movement of the filters.
[0085] In the embodiments described above where scanning of the
first and second surfaces 18, 20 of the support structure 16 may be
performed sequentially, the individual steps of scanning the first
and second surfaces 18, 20 of the support structure 16 may be
performed in a number of ways. For instance, it may be possible to
scan a single line of the first surface 18, then scan a single line
of the second surface 20, then gradually move the first and second
surfaces 18, 20 relative to the excitation radiation 58, 62 by
translating the support structure 16, the directing optics 30, the
focusing optics 32, or some combination thereof, in order to repeat
these steps of scanning individual lines. Alternatively, entire
regions of the first surface 18 may be scanned before regions of
the second surface 20 are scanned. The individual processing steps
taken may depend upon several variables including the particular
configuration of the biological component sites 12, 14 on the
surfaces 18, 20 as well as other variables, including environmental
and operating conditions.
[0086] Particular embodiments may allow for simultaneous excitation
of multiple surfaces of the support structure 16. For instance,
FIG. 20 illustrates an embodiment utilizing dual radiation sources
and dual detectors. However, in this embodiment, the first surface
18 and the second surface 20 of the support structure 16 may be
simultaneously scanned. This may be accomplished using focusing
lenses 164, 166, 168, 170 and a dichroic mirror 172 along the
excitation path in order to switch surfaces and filters 158, 160 to
achieve multiple color channels. Again, this illustrated embodiment
may also be extended to any number of detectors to improve
throughput, scanning efficiency, and to reduce movement of the
filters and other system components.
[0087] FIG. 21 illustrates another embodiment utilizing dual
radiation sources and dual detectors which allows for simultaneous
scanning of the first and second surfaces 18, 20 of the support
structure 16. In this illustrated embodiment, however, not only are
focusing lenses 164, 166, 168, 170 and a dichroic mirror 172 used
in the excitation path but focusing lenses 174, 176 may be used
just upstream of the first and second detectors 36, 162 in
conjunction with the filters 158, 160 along the emission path in
order to switch surfaces and achieve multiple color channels. Once
again, this illustrated embodiment may also be extended to use any
number of detectors to increase throughput and scanning
efficiency.
[0088] For instance, FIG. 22 illustrates an embodiment utilizing
multiple radiation sources and multiple detectors which are capable
of simultaneously outputting multiple channels with few moving
parts. In the illustrated embodiment, radiation sources 22 and 24
have been replaced by radiation source groups 178 and 180 which are
capable of outputting multiple radiation sources and varying
wavelengths. In addition, detectors 36 and 38 have been replaced by
detector groups 182 and 184 in the illustrated embodiment. These
detector groups 182, 184 are similarly capable of detecting
multiple color channels. This embodiment therefore illustrates the
considerable adaptability of the present techniques to a range of
configurations capable of imaging components on multiple surfaces
of the support.
[0089] In the embodiments described above where scanning of the
first and second surfaces 18, 20 of the support structure 16 may be
performed simultaneously, focusing of the excitation radiation 58
source may be accomplished in several various ways. For instance,
it may be possible to focus the excitation radiation 58 on one of
the surfaces preferentially over the other surface. In fact, due to
the nature of the configuration of the first surface 18 with
respect to the second surface 20, it may be necessary to do so.
However, alternate focusing techniques may be employed depending on
the specific configuration of the support structure 16. Moreover,
it may be advantageous in these various configurations to first
image the upper surface (i.e., the surface closer to the radiation
source) in order to reduce photobleaching of the components on that
surface that could result from first imaging the lower surface
(i.e., the surface farther from the radiation source). Such
selection of which surface to image may apply both when the
surfaces are imaged sequentially as well as when they are imaged
simultaneously.
[0090] In addition, the embodiments disclosed above have
illustrated an epifluorescent imaging scheme wherein the excitation
radiation is directed toward the surfaces of the support structure
16 from a top side, and returned fluorescent radiation is received
from the same side. However, the techniques of the present
invention may also be extended to alternate arrangements. For
instance, these techniques may also be employed in conjunction with
TIR imaging whereby the surfaces of the support structure are
irradiated from a lateral side with radiation directed at an
incident angle within a range of critical angles so as to convey
the excitation radiation within the support or into the support
from a prism positioned adjacent to it. TIR techniques can be
carried out as described, for example, in U.S. Patent Application
Publication No. 2005/0057798, which is hereby incorporated by
reference. Such techniques cause fluorescent emissions from the
components that are conveyed outwardly for imaging, while the
reflected excitation radiation exits via a side opposite from that
through which it entered. Here again, biological components on the
multiple surfaces may be imaged sequentially or simultaneously.
[0091] For example, in FIG. 23, a TIR biological sample imaging
system 186 is illustrated diagrammatically. A support structure 188
may be used which includes multiple flow lanes 190 containing
biological components. For example, the support structure 188 may
be a flow cell through which reagents, flushes, and other fluids
may be introduced using the flow lanes 190 to contact emissive
components attached to the surface of the flow cell. The support
structure 188 may be supported by a prism 192. In the TIR
biological sample imaging system 186, the radiation source 194 may
output a radiation beam 196 through the prism 192 from a lateral
side of the support structure 188. The radiation beam 196 may, for
instance, be directed toward a bottom surface of one of the flow
lanes 190 of the support structure 188, thereby exciting emissive
components attached to the surface.
[0092] As discussed in further detail below, as long as the
incident angle of the radiation beam 196 is within the range of
critical angles (as described, for example, in US 2005/0057798), a
portion of the radiation beam 196 will be reflected off the bottom
surface whereas a separate fluorescent emission beam from
surface-bound emissive components will be directed toward focusing
optics 198. Typically, a well collimated radiation beam is used to
prevent spread of angles within the beam, thereby preventing
unwanted hindrance of total internal reflectance. The fluorescent
emission beam may propagate back through the focusing optics 198,
directing optics 200, and detection optics 202 which may direct the
beam toward a detector 204. The focusing optics 198, directing
optics 200, detection optics 202, and detector 204 may operate in
much the same manner as with the epifluorescent techniques
discussed above. In the TIR biological sample imaging system 186,
the focusing light source 206 may be used as a separate light
source from the radiation source 194 to focus the optics on a
particular surface to be imaged. For instance, the focusing light
source 206 may be directed to the directing optics 200 where it is
redirected toward the focusing optics 198 which are used to focus
the system on a particular surface of the support structure
188.
[0093] The TIR biological sample imaging system 186 may also
include a translation system 208 for moving the support structure
188 and prism 192 in one or more dimensions. The translation system
208 may be used with focusing, redirecting the radiation source 194
to different areas of the support structure 188, as well as for
moving the support structure 188 and prism 192 to a heating/cooling
station 210. The heating/cooling station 210 may be used to heat
and cool the support structure 188 before and after imaging. In
addition, a control/processing system 212 may be used to control
operation of the radiation source 194, the focusing light source
206, and the heating/cooling station 210, movement and focusing of
the focusing optics 198, the translation system 208, and the
detection optics 202, and acquisition and processing of signals
from the detector 204.
[0094] As discussed above, the TIR method of imaging may be used to
direct the radiation beam 196 from a lateral side of the support
structure 188, as illustrated in FIG. 24. Each flow lane 190 of the
support structure 188 may include a bottom surface 214 and a top
surface 216 and emissive components can optionally be attached to
either or both surface. In the illustrated embodiment, the
radiation beam 196 is directed toward a bottom surface 214 of one
of the flow lanes 190 of the support structure 188. Part of the
radiation beam 196 may be reflected off the bottom surface 214 of
the flow lane 190, as depicted by reflected light beam 218.
However, as long as the incident angle of the radiation beam 196 is
within the range of critical angles, a separate fluorescent
emission beam 220 may be emitted from emissive components toward
the focusing optics 198 which in the illustrated embodiment is a
lens objective 222. Indeed, directing the radiation beam 196 at a
bottom surface 214 of a flow lane 190 of the support structure 188
is a typical implementation of the TIR imaging method. However, in
doing so, imaging data which may be collected from a top surface
216 of a flow lane 190 of the support structure 188 may be
overlooked.
[0095] Therefore, the orientation of the radiation source 194
and/or the support structure 188 and prism 192 may be adjusted in
order to allow the radiation beam 196 to not be directed at a
bottom surface 214 of a flow lane 190 of the support structure 188,
as illustrated in FIG. 25. In the illustrated embodiment, the
radiation beam 196 is oriented so that the radiation beam 196
passes through the prism 192 and support structure 188 until
contacting an air/glass interface 224 of the support structure 188
at which point the radiation beam 196 is redirected toward a top
surface 216 of a flow lane 190 of the support structure 188. At
this point, part of the radiation beam 196 may be reflected back
toward another air/glass interface 224 of the support structure
188. However, a separate fluorescent emission beam 220 may be
emitted from an emissive component on the top surface 216 toward
the lens objective 222. Using this technique, top surfaces 216 of
the flow lanes 190 of the support structure 188 may be imaged using
TIR imaging methods. This, in effect, may allow for double the
imaging data output for cluster based sequencing applications while
keeping other variables, such as surface coating, cluster creation,
and sequencing, the same.
[0096] In order to accomplish this TIR imaging of top surfaces 216
of the flow lanes 190 of the support structure 188, the radiation
beam 196 reaches the air/glass interface 224 of the support
structure 188 unperturbed. To do so, the radiation beam 196 does
not first come into contact with emissive components in adjacent
flow lanes 190. To do so, either the radiation beam 196 may be
directed around the adjacent flow lanes 190 or the adjacent flow
lanes 190 may be index matched with the support structure 188
material. In some embodiments, the flow lanes 190 may be spaced
within the support structure 188, leaving sufficient room between
the flow lanes 190 for the radiation beam 196 to pass. However,
spacing the flow lanes 190 in this manner may ultimately reduce the
amount of emissive components which may be imaged. Therefore, in
other embodiments, it may be possible to accomplish the same effect
by temporarily filling alternate flow lanes 190 with index matching
fluid. Doing so may allow for easier direction of the radiation
beam 196 toward a top surface 216 of a flow lane 190 of the support
structure 188.
[0097] It may also be possible to direct the radiation beam 196 in
such a way that it bounces off multiple top surfaces 216 of flow
lanes 190 of the support structure 188, as illustrated in FIG. 26.
In order to accomplish this, the spacing of the flow lanes 190 can
be matched with the angle of radiation beam 196 such that the
radiation beam 196 is able to pass by the flow lanes 190, such that
it reaches the air/glass interface 224 of the support structure 188
unperturbed, while also being able to bounce back and forth between
top surfaces 216 of flow lanes 190 and the air/glass interface 224
of the support structure 188. As described above, in certain
embodiments, some of the flow lanes 190 may be filled with an index
matching fluid, such that these index-matched flow lanes 190
effectively become "invisible" to the radiation beam 196. In other
words, the radiation beam 196 may be allowed to pass through the
index-matched flow lanes 190. By allowing the radiation beam 196 to
pass through the index-matched flow lanes 190, the support
structure 188 may be used in multiple configurations without the
need of varying the spacing of the flow lanes 190.
[0098] In some embodiments, mirrors 226 or other suitable
reflective material may be used within certain flow lanes 190,
facilitating this multi-bounce technique. In any event, assuming N
number of flow lanes 190, it may only be possible to image N-2
number of top surfaces 216 of the flow lanes 190 in this manner due
to the fact that the outer flow lanes 190 on either side of the
support structure 188 may not be accessible using these techniques.
However, modification of the prism 192 and/or support structure 188
may allow for imaging of the top surfaces 216 of these outermost
flow lanes 190. For instance, the support structure 188 may be
designed to fit within the prism 192, allowing the radiation beam
196 to propagate into a lateral side of the support structure
188.
[0099] In some embodiments, as discussed above briefly with respect
to FIG. 23, the support structure 188 may be moved to a
heating/cooling station 210, for example, by the action of the
translation system 208. The heating/cooling station 210 may be
configured to both heat and cool the support structure 188 before
and after imaging. The heating/cooling station 210 may, in fact, be
configured to heat and cool both a top surface 228 and a bottom
surface 230 of the support structure 188, as illustrated in FIG.
27. Indeed, all surfaces of the support structure 188 may be heated
or cooled at the heating/cooling station 210. In this manner, it
may further be possible to heat and cool both the top surfaces 216
and bottom surfaces 214 of the flow lanes 190 of the support
structure 188 by directly contacting one or more surfaces of the
flow cell with a heating or cooling device. This, of course, may
facilitate the development of biological components within the flow
lanes 190 of the support structure 188 and, therefore, facilitate
imaging. Although use of the heating/cooling station 210 has been
presented herein with respect to the TIR imaging methods, the
heating/cooling station 210 may also be used to heat and cool
multiple sides of a support structure used in conjunction with the
epifluorescent imaging methods discussed herein.
[0100] In particular embodiments, the current invention utilizes
sequencing-by-synthesis (SBS). In SBS, four fluorescently labeled
modified nucleotides are used to determine the sequence of
nucleotides for nucleic acids present on the surface of a support
structure such as a flow cell. Exemplary SBS systems and methods
which can be utilized with the apparatus and methods set forth
herein are described in U.S. Pat. No. 7,057,026; U.S. Patent
Application Publication Nos. 2005/0100900, 2006/0188901,
2006/0240439, 2006/0281109, and 2007/0166705; and PCT Publication
Nos. WO 05/065814, WO 06/064199, and WO 07/010251; each of which is
incorporated herein by reference.
[0101] In particular uses of the apparatus and methods herein, flow
cells containing arrayed nucleic acids are treated by several
repeated cycles of an overall sequencing process. The nucleic acids
are prepared such that they include an oligonucleotide primer
adjacent to an unknown target sequence. To initiate the first SBS
sequencing cycle, one or more differently labeled nucleotides and a
DNA polymerase are flowed into the flow cell. Either a single
nucleotide can be added at a time, or the nucleotides used in the
sequencing procedure can be specially designed to possess a
reversible termination property, thus allowing each cycle of the
sequencing reaction to occur simultaneously in the presence of all
four labeled nucleotides (A, C, T, G). Following nucleotide
addition, the features on the surface can be imaged to determine
the identity of the incorporated nucleotide (based on the labels on
the nucleotides). Then, reagents can be added to the flow cell to
remove the blocked 3' terminus (if appropriate) and to remove
labels from each incorporated base. Such cycles are then repeated
and the sequence of each cluster is read over the multiple
chemistry cycles.
[0102] Other sequencing methods that use cyclic reactions wherein
each cycle includes steps of delivering one or more reagents to
nucleic acids on a surface and imaging the surface bound nucleic
acids can also be used such as pyrosequencing and sequencing by
ligation. Useful pyrosequencing reactions are described, for
example, in U.S. Pat. No. 7,244,559 and U.S. Patent Application
Publication No. 2005/0191698, each of which is incorporated herein
by reference. Sequencing by ligation reactions are described, for
example, in Shendure et al. Science 309:1728-1732 (2005); and U.S.
Pat. Nos. 5,599,675 and 5,750,341, each of which is incorporated
herein by reference.
[0103] The methods and apparatus described herein are also useful
for detection of features occurring on surfaces used in genotyping
assays, expression analyses and other assays known in the art such
as those described in U.S. Patent Application Publication Nos.
2003/0108900, US 2003/0215821, and US 2005/0181394, each of which
is incorporated herein by reference.
[0104] While only certain features of the invention have been
illustrated and described herein, many modifications and changes
will occur to those skilled in the art. It is, therefore, to be
understood that the appended claims are intended to cover all such
modifications and changes as fall within the true spirit of the
invention.
* * * * *