US20140247425A1 - Multi-Functional Adaptive Optics Retinal Imaging - Google Patents

Multi-Functional Adaptive Optics Retinal Imaging Download PDF

Info

Publication number
US20140247425A1
US20140247425A1 US14/192,183 US201414192183A US2014247425A1 US 20140247425 A1 US20140247425 A1 US 20140247425A1 US 201414192183 A US201414192183 A US 201414192183A US 2014247425 A1 US2014247425 A1 US 2014247425A1
Authority
US
United States
Prior art keywords
mode
eye
oct
slo
image
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Abandoned
Application number
US14/192,183
Inventor
Daniel X. Hammer
R. Daniel Ferguson
Mircea Mujat
Anket H. Patel
Nicusor V. Iftimia
Stephen Burns
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Physical Sciences Corp
Original Assignee
Physical Sciences Corp
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Physical Sciences Corp filed Critical Physical Sciences Corp
Priority to US14/192,183 priority Critical patent/US20140247425A1/en
Publication of US20140247425A1 publication Critical patent/US20140247425A1/en
Assigned to PHYSICAL SCIENCES, INC. reassignment PHYSICAL SCIENCES, INC. ASSIGNMENT OF ASSIGNORS INTEREST (SEE DOCUMENT FOR DETAILS). Assignors: PATEL, ANKIT H., BURNS, STEPHEN, HAMMER, DANIEL X., IFTIMIA, NICUSOR V., FERGUSON, R. DANIEL, MUJAT, MIRCEA
Abandoned legal-status Critical Current

Links

Images

Classifications

    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61BDIAGNOSIS; SURGERY; IDENTIFICATION
    • A61B3/00Apparatus for testing the eyes; Instruments for examining the eyes
    • A61B3/10Objective types, i.e. instruments for examining the eyes independent of the patients' perceptions or reactions
    • A61B3/1015Objective types, i.e. instruments for examining the eyes independent of the patients' perceptions or reactions for wavefront analysis
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61BDIAGNOSIS; SURGERY; IDENTIFICATION
    • A61B3/00Apparatus for testing the eyes; Instruments for examining the eyes
    • A61B3/10Objective types, i.e. instruments for examining the eyes independent of the patients' perceptions or reactions
    • A61B3/102Objective types, i.e. instruments for examining the eyes independent of the patients' perceptions or reactions for optical coherence tomography [OCT]
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61BDIAGNOSIS; SURGERY; IDENTIFICATION
    • A61B3/00Apparatus for testing the eyes; Instruments for examining the eyes
    • A61B3/10Objective types, i.e. instruments for examining the eyes independent of the patients' perceptions or reactions
    • A61B3/1025Objective types, i.e. instruments for examining the eyes independent of the patients' perceptions or reactions for confocal scanning
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61BDIAGNOSIS; SURGERY; IDENTIFICATION
    • A61B3/00Apparatus for testing the eyes; Instruments for examining the eyes
    • A61B3/10Objective types, i.e. instruments for examining the eyes independent of the patients' perceptions or reactions
    • A61B3/12Objective types, i.e. instruments for examining the eyes independent of the patients' perceptions or reactions for looking at the eye fundus, e.g. ophthalmoscopes
    • A61B3/1225Objective types, i.e. instruments for examining the eyes independent of the patients' perceptions or reactions for looking at the eye fundus, e.g. ophthalmoscopes using coherent radiation
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61BDIAGNOSIS; SURGERY; IDENTIFICATION
    • A61B3/00Apparatus for testing the eyes; Instruments for examining the eyes
    • A61B3/10Objective types, i.e. instruments for examining the eyes independent of the patients' perceptions or reactions
    • A61B3/14Arrangements specially adapted for eye photography

Definitions

  • the invention relates generally to retinal imaging, and more particularly, to a multi-functional retinal imaging system that combines adaptive optics corrected optical coherence tomography and scanning laser ophthalmoscopy channels.
  • Adaptive optics (AO) and optical coherence tomography (OCT) can provide information on cellular and sub-cellular structures in the live eye.
  • OCT uses low-coherence interferometry to de-link axial resolution from the diffraction-limited depth-of-field for generation of micron-level axial resolution optical depth sections.
  • AO is a technique to enhance the transverse resolution and depth sectioning capabilities by detection and correction of ocular aberrations. It has been integrated into instruments for full-field fundus imaging, scanning laser ophthalmoscopy (SLO), and Fourier domain (FD) OCT.
  • AO has also become a staple for vision researchers as a tool to explore the structural and functional aspects of vision and its disruption by disease. While AO has yet to make a full transition from research lab to clinic, OCT is now a standard diagnostic procedure for glaucoma, macular holes, macula edema, retinal detachments, and other retinal pathologies. FDOCT has now supplanted time domain(TD) OCT because of its advantages of higher speeds (near video rate), higher signal-to-noise ratio via simultaneous multiplexed acquisition of depth voxels, and lower phase noise. Clinical FDOCT systems are available commercially from several companies.
  • FDOCT comes in two basic varieties depending upon whether the source arm (swept source, SS) or the detection arm (spectral domain, SD) of the interferometer is altered.
  • SS source arm
  • SD detection arm
  • SDOCT systems have slightly better axial resolution
  • SSOCT systems have increased depth range and accessibility to longer wavelengths.
  • Ophthalmic OCT research systems at 1 ⁇ m, including initial reports configured with AO have shown significantly improved choroidal penetration compared to 850 nm systems. In addition to increased penetration, ocular dispersion is less at 1 ⁇ m than at 850 nm.
  • SLO and OCT are complementary tools for imaging the retina.
  • OCT is an interferometric technique, whose fast 2-D frame axis is cross-sectional (i.e., lateral-axial) with micron level axial resolution that yields excellent sectioning capability. OCT is therefore better suited for visualization of retinal layers.
  • SLO is a confocal technique whose fast 2-D frame axis is en-face (i.e. lateral-lateral) with sensitivity to multiply-scattered light. SLO is therefore better able to resolve photoreceptors, blood flow, and capillaries with higher contrast than OCT.
  • SLO systems can be configured to collect fluorescence signals.
  • the invention features a multi-functional retinal imager that combines adaptive optics-corrected Fourier domain optical coherence tomography and scanning laser ophthalmoscopy channels.
  • the adaptive optics provide high lateral resolution and a narrow depth of focus by real-time correction of ocular aberrations that distort the wavefront and blur the focused beam in the eye.
  • OCT is a technique for micron-level axial resolution and depth sectioning.
  • the technology can include both spectrometer-based and swept source-based FDOCT implementations.
  • a wide field line scanning ophthalmoscope (LSO) and a retinal tracker (RT) can also be included in the system.
  • a retinal imaging system can combine AO-corrected scanning laser ophthalmoscopy, swept source Fourier domain optical coherence tomography imaging, and wide field line scanning ophthalmoscopy imaging modes, and retinal tracking in a single, compact clinical platform.
  • the technology features an optical apparatus including a system of optical components capable of operating in a scanning laser ophthalmoscope (SLO) mode and an optical coherence tomography (OCT) mode.
  • the system of optical components includes a first optical module for the SLO mode, a second optical module for the OCT mode, and a first scanning device.
  • the first optical module for the SLO mode includes a first source adapted to provide a first imaging beam for the SLO mode and a first detection device configured to receive a first signal associated with a first image of a retina of an eye.
  • the second optical module for the OCT mode includes a second source adapted to provide a second imaging beam for the OCT mode and a second detection device configured to receive a second signal associated with a second image of the retina.
  • the first scanning device is configured to move the first imaging beam along the retina in the slow axis of the SLO mode to acquire the first image and (ii) to move the second imaging beam along the retina in the fast axis of the OCT mode to acquire
  • a method of imaging a retina of an eye includes acquiring a SLO image of the eye by receiving, on a first detector, a first light returning from the eye and providing a first electrical signal responsive to the first light at each of a plurality of locations along the first detector.
  • the first electrical signal is indicative of the SLO image of the eye.
  • the method includes acquiring an OCT image of the eye by receiving, on a second detector, a second light returning from the eye and providing a second electrical signal responsive to the second light at each of a plurality of locations along the second detector.
  • the second electrical signal is combined with a reference signal from a reference arm.
  • the second electrical signal and the reference signal are associated with the OCT image of the eye.
  • the method also includes scanning, using a first scanning device, (i) a first imaging beam along the retina in the slow axis of the SLO mode to acquire the SLO image and (ii) a second imaging beam along the retina in the fast axis of the OCT mode to acquire the OCT image.
  • an optical apparatus including a system of optical components capable of operating in a scanning laser ophthalmoscope (SLO) mode and an optical coherence tomography (OCT) mode.
  • the system of optical components includes at least two spherical minors, at least two deformable minors (DM's) positioned behind the at least two spherical minors, a beamsplitter positioned behind the at least two deformable minors, an OCT optical module introduced by the beamsplitter, and a SLO optical module behind the beamsplitter.
  • Each spherical minor has a diameter greater than 20 cm and is positioned relative to the eye.
  • the optical apparatus also includes first, second and third scanning devices.
  • the first scanning device is positioned between the beamsplitter and the eye.
  • the first scanning device is configured (i) to move a first imaging beam along the retina in the slow axis of the SLO mode to acquire an SLO image and (ii) to move a second imaging beam along the retina in the fast axis of the OCT mode to acquire an OCT image.
  • the second scanning device is positioned behind the beamsplitter.
  • the second scanning device is configured to move the first imaging beam along the retina in the fast axis of the SLO mode to acquire the SLO image.
  • the third scanning device is positioned between the beamsplitter and the eye.
  • the third scanning device is configured to move the second imaging beam along the retina in the slow axis of the OCT mode to acquire the OCT image.
  • the OCT mode can include a Fourier domain OCT channel configured to be spectrometer-based or swept source-based.
  • the system of optical components can be adapted to simultaneously image the same retinal coordinates in the SLO mode and OCT module.
  • the optical apparatus includes a second scanning device configured to move the first imaging beam along the retina in the fast axis of the SLO mode to acquire the first image and a third scanning device configured to move the second imaging beam along the retina in the slow axis of the OCT mode to acquire the second image.
  • the first scanning device, the second scanning device and the third scanning device can be positioned at pupil conjugates in the system of optical components.
  • the first scanning device can be mounted to the third scanning device at a pupil conjugate.
  • the second imaging beam of the OCT mode is introduced by a beamsplitter positioned between the eye and the SLO module.
  • the third scanning device can be configured to scan the first imaging beam to generate a mosaic image of the eye.
  • a third optical module is configured to (i) detect an optical distortion and (ii) correct the optical distortion in at least one of the first or second imaging beams scanned on the eye.
  • the third optical module can include a wavefront sensor adapted to detect the optical distortion and a wavefront compensator adapted to correct the optical distortion in the first or second imaging beam.
  • two wavefront compensators are positioned between the beamsplitter and the eye.
  • a dual-deformable minor configuration can be used to provide simultaneous, high-fidelity, wide dynamic range correction of lower- and higher-order ocular aberrations.
  • a fourth optical module can be configured to operate in a line scanning ophthalmoscope (LSO) mode.
  • the fourth optical module can include a third source adapted to provide a third imaging beam in a line focus configuration for the LSO mode.
  • the fourth optical module can be configured to (i) scan the third imaging beam in the line focus configuration along the retina in a second dimension and (ii) descan the second light returning from the eye in the second dimension. The light returning from the eye is directed to a third detection device.
  • the system of optical components can include a fifth optical module adapted to track a reference feature of the retina of the eye.
  • the first optical module can be adapted to control the position of the first imaging beam relative to the reference feature to correct for motion of the eye.
  • the system of optical components can include a sixth optical module adapted to provide a fluorescence imaging channel.
  • a LCD-based fixation target can be used to acquire images of the eye in at least one of the SLO mode, the OCT mode, or the LSO mode.
  • the system of optical components includes at least two spherical mirrors.
  • Each spherical mirror has a diameter greater than 20 cm.
  • the spherical mirrors are positioned relative to the eye and configured to provide a field of view greater than 30 degrees.
  • the wavelength of the second imaging beam of the OCT mode can be selected to match a physical property of the tissue.
  • the optical system can be used for one or more of the following applications:
  • FIG. 1 shows a schematic diagram of an optical apparatus for imaging a retina of an eye.
  • FIG. 2 shows a block diagram of an exemplary multimodal AO system.
  • FIG. 3 shows an unfolded optical layout for a multimodal AO system.
  • FIG. 4 shows a schematic diagram of scanning axes for the SLO and OCT.
  • FIG. 5 show an example of an instrumentation layout.
  • FIG. 6 shows the point spread functions (PSF's) at retinal conjugates two and four for focused illumination.
  • FIG. 7 shows an example of the AO performance achieved in one human subject.
  • FIG. 8 shows examples from 4 of the 6 subjects in each of the three primary imaging modes (LSO, SLO, OCT).
  • FIG. 9 shows single and 4-frame average cross-sectional FDOCT images through the fovea for one subject that was imaged with both an 850-nm spectrometer-based instrument and the current 1050-nm swept source-based AO-FDOCT imager.
  • FIG. 10 shows an AOSLO montage in the central ⁇ 3 deg. for one subject.
  • FIG. 11 shows the results compared to no registration and registration frame-by-frame.
  • FIG. 12 shows a registered stack of multimodal AO images from a slow strip scan in the presence of above average eye movements (for a control subject).
  • FIG. 13 shows cone photoreceptor counts on several retinal patches at various eccentricity from a single 2-deg. AOSLO scan near the fovea (identifiable in the images) for 4 subjects using manual and automated methods.
  • FIG. 14 shows an example of the AO performance achieved in one human subject.
  • FIG. 15 shows an exemplary SLO timing board functional schematic.
  • FIG. 1 shows an optical apparatus 10 including a system of optical components capable of operating in a scanning laser ophthalmoscope (SLO) mode and an optical coherence tomography (OCT) mode.
  • the system of optical components includes a first optical module 14 for the SLO mode, a second optical module 18 for the OCT mode, and a first scanning device 22 .
  • the first optical module 14 for the SLO mode includes a first source adapted to provide a first imaging beam 24 for the SLO mode and a first detection device configured to receive a first signal associated with a first image of a retina 26 of an eye 30 .
  • the second optical module 18 for the OCT mode includes a second source adapted to provide a second imaging beam 32 for the OCT mode and a second detection device configured to receive a second signal associated with a second image of the retina 26 .
  • the first scanning device 22 is configured to move the first imaging beam along the retina 26 in the slow axis of the SLO mode to acquire the first image and to move the second imaging beam along the retina 26 in the fast axis of the OCT mode to acquire the second image.
  • the optical apparatus 10 can include a second scanning device 34 and a third scanning device 38 .
  • the second scanning device 34 can be configured to move the first imaging beam along the retina in the fast axis of the SLO mode to acquire the first image.
  • the third scanning device 38 can be configured to move the second imaging beam along the retina in the slow axis of the OCT mode to acquire the second image.
  • the first scanning device 22 , the second scanning device 34 and the third scanning device 38 can be positioned at pupil conjugates in the system of optical components.
  • the first scanning device 22 is mounted to the third scanning device 38 at a pupil conjugate.
  • the third scanning device 38 can be configured to scan the first imaging beam to generate a mosaic image of the eye.
  • a beamsplitter 42 can be used to introduce the second imaging beam of the OCT mode.
  • the beamsplitter 42 can be positioned between the eye 30 and the SLO module 14 .
  • the optical apparatus 10 can include a third optical module configured to (i) detect an optical distortion and (ii) correct the optical distortion in at least one of the first or second imaging beams scanned on the eye.
  • the third optical module can include a wavefront sensor 46 adapted to detect the optical distortion and at least one wavefront compensator 50 adapted to correct the optical distortion in the first or second imaging beam.
  • a first wavefront compensator and a second wavefront compensator are positioned between the beamsplitter 42 and the eye 30 .
  • the optical apparatus 10 can include at least two spherical minors 54 .
  • Each spherical minor 54 can have a large surface area.
  • each spherical mirror 54 can have a diameter greater than 20 cm.
  • the spherical mirrors 54 can be positioned relative to the eye and configured to provide a field of view greater than 30 degrees. In some embodiments, the field of view is about 15 to 35 degrees.
  • An advantage of the wide field front end is that the SLO and OCT scans can be made large. A user can perform an initial low resolution, large scan to map the entire macula and then perform a high resolution scan of specific targets.
  • FIG. 2 shows a block diagram of an exemplary multimodal AO system.
  • the optical design can significantly reduce inherent aberrations providing a wide field of regard (for example, ⁇ 33 degrees) for the SLO and SSOCT fields while fully integrating the LSO imaging and RT reflectometer.
  • the AO components can include a Hartmann-Shack wavefront sensor (HS-WS) and two deformable minors in a woofer-tweeter configuration for high-fidelity, wide dynamic range correction of lower- and higher-order ocular aberrations.
  • Other features of the system include a custom, FPGA-based OCT digitizer and processing board and a high resolution LCD-based fixation target.
  • the design achieves an extremely compact instrument footprint suitable for clinical portability. The system performance was validated on model eyes and human and animal subjects.
  • FIG. 2 shows a LSO image 100 , a HS-WS image 101 , an AOSLO image 102 and FDOCT image 103 .
  • the imaging system shown in FIG. 2 can be used to image human eyes 240 or animals 104 .
  • the imaging system includes a first module/SLO channel 116 , a second module/FDOCT channel (e.g., a spectrometer-based FDOCT channel 117 or a swept source based FDOCT channel 118 ), a third module/AO module 115 , a fourth module/LSO channel 205 , a fifth module/retinal tracker 206 , and a sixth module/fluorescence channel 119 .
  • a first module/SLO channel 116 e.g., a spectrometer-based FDOCT channel 117 or a swept source based FDOCT channel 118
  • a third module/AO module 115 e.g., a fourth module/LSO channel 205 , a
  • the SLO channel 116 includes a source 225 (e.g., a superluminescent diode), a detection device 120 (e.g., a confocal detector), a SLO timing board 121 , and a framegrabber 122 .
  • the FDOCT channel can be a spectrometer-based FDOCT channel 117 or a swept source based FDOCT channel 118 coupled to the optical system by a fiber connector 207 .
  • Both FDOCT channels includes a framegrabber 122 , a real-time FDOCT processor/controller 123 , an optical delay line 125 , and a fiber coupler 223 .
  • the SDOCT 117 utilizes a source 225 (e.g., a superluminescent diode) and a spectrometer 124 .
  • the SSOCT 118 utilizes a swept source 226 , a high speed digitizer 128 and a balanced detector 227 .
  • the third module/AO module 115 includes image scanners 110 , at least one deformable mirror/wavefront compensator 111 , a DM controller 112 , a HS-WS 113 , and a framegrabber 122 .
  • the fourth module/LSO channel 205 includes a LSO module 250 and a framegrabber 122 .
  • the fifth module/retinal tracker 206 includes a tracker source and reflectometer 107 , a tracker controller 108 , and tracker scanners 109 .
  • An exemplary LSO system is described in U.S. Pat. No. 6,758,564, the disclosure of which is herein incorporated by reference in its entirety.
  • the LSO can be combined with a retinal tracking system to form a TSLO.
  • An exemplary tracking system is described in U.S. Pat. No. 5,797,941, the disclosure of which is herein incorporated by reference in its entirety.
  • Stabilized retinal imaging with adaptive optics is described in U.S. Pat. No.
  • the sixth module/fluorescence channel 119 includes a fluorescence excitation beam 241 , a fluorescence emission beam 242 , a wavelength selection filter 239 , a pre-amplifier 129 , a photomultiplier tube (PMT) 130 , and a framegrabber 122 .
  • the source can be any fluorescent source (e.g., white light, laser, SLD, LED, etc.) with sufficient power to excite the appropriate retinal fluorophores.
  • the fluorescence channel can include dichroic beamsplitters to combine visible excitation and emission beam with NIR imaging beams and to separate excitation and emission beams.
  • the filter 239 can be a barrier (notch) filter to remove all wavelengths except fluorescence on the PMT detector. A filter can be selected based on the desired fluorophore.
  • the imaging system shown in FIG. 2 includes various beamsplitters and optics for coupling the various modules so that measurements can be taken.
  • Beamsplitters include pellicle beamsplitter 213 and dichroic beamsplitters 217 .
  • One skilled in the art will recognize that other optics can be used to couple the optical modules.
  • Spherical mirrors 219 can be used to provide a wide field of view.
  • the imaging system can include a LCD-based fixation target 237 .
  • the imaging system can be configured to accommodate two or more output pupil sizes.
  • an optical component 210 can be used to couple a second optical imaging line to the instrument.
  • the optical component is a flip mount. In some embodiments, this is desirable so that animals 104 can be imaged or so that humans with different pupil sizes can be imaged.
  • An integrated small animal imaging port (accessed from a flip mounted minor) can change the pupil magnification for AO-correction in small animals, which have smaller dilated pupil sizes.
  • the beam diameter at the output for two exemplary configurations is 7.5 and 2.5 mm. Smaller pupil sizes can provide for larger depth of focus.
  • the optical component or the flip mount can be actuated manually or automatically by a motor controlled by software on a computer.
  • a wide field (>30 degree) optical design allows high resolution image field (typically 1-3 degrees) to be placed anywhere in the larger field of regard without re-positioning the patient or moving the fixation target. In certain embodiments, the field is about 15 to 35 degrees.
  • With dynamic AO correction variability in system aberrations across the wide field of regard can be compensated in real-time. Placing optical elements at pupil conjugates and introducing beams with dichroic beamsplitters allows simultaneous acquisition of AO-correct SLO and OCT images.
  • the SLO resonant scanner is placed behind the DMs and the OCT beam is introduced with a dichroic beamsplitter between the resonant scanner and the DMs.
  • the HS-WS is acquired synchronously so that AO-correction is uniform across the SLO or OCT image field.
  • the instrumentation is also can be designed so that the LSO image is acquired and the RT operates simultaneously.
  • the SLO and OCT images can be registered (e.g., imaging same retinal coordinates).
  • a dual-DM configuration can provide simultaneous high-fidelity, wide dynamic range correction of lower- and higher-order ocular aberrations. This allows AO corrections to be applied to a broader clinical population.
  • the lower-order aberrations up to 5 Zernike orders
  • the higher order aberrations up to 8 Zernike orders
  • the optical system includes an integrated LSO/RT optical head and beam path.
  • the optics and instrumentation are slightly less complex with the fully integrated LSO/RT beam paths. This is made possible by the wide field optical design.
  • the LSO and RT beams are typically at different wavelengths than the SLO and OCT beams.
  • FIG. 3 shows an unfolded optical layout. All imaging modes access a common beam path comprised of all-reflective optical elements to minimize chromatic aberrations and maintain high throughput. Ten spherical minors 219 are used to transfer and magnify (or minify) the retinal and pupil planes to successive conjugates. The magnification of each relay is set to nearly fill the physical dimensions of each component. All scanners and DMs are placed at pupil conjugates to pivot about and correct at a single plane. The tracking galvanometers are placed at conjugates to the eye's center-of-rotation to simultaneously track retinal and pupil shifts.
  • the SLO channel 200 utilizes a confocal pinhole 209 and an avalanche photodiode (APD) 208 to collect light returning from the retina and source 225 .
  • APD avalanche photodiode
  • the OCT channel can be configured in a spectrometer based 203 or a swept source-based 204 architecture. Both architectures can be fiber connected 207 to the main optical line by a dichroic beamsplitter 217 , a lens 211 and an achromatizer 234 .
  • the spectrometer based OCT 203 utilizes a source 225 , a circulator 224 fiber connected 207 to a detection device including a lens 211 , a transmission grating 229 , a series of objective lenses 230 , and a linear detector 233 .
  • the SDOCT 203 also includes a polarization controller 221 and a 2 ⁇ 2 fiber coupler 223 fiber connected 207 to an optical delay line including a lens 211 , dispersion compensation cube 232 , a neutral density filter 231 and mirrors 228 .
  • the optical delay line uses a folded arrangement—five passes off the mirrors 228 - to match the ⁇ 4.3 m sample pathlength.
  • the swept source-based OCT 204 utilizes a swept source 226 , a circulator 224 connected to a balanced detector 227 and a fiber coupler 223 .
  • the SSOCT 204 includes a polarization controller 221 and an optical delay line.
  • the balanced detector provides efficient light collection and common mode signal rejection.
  • the AO design includes a dual minor 254 (e.g., woofer 254 w and tweeter 254 t ) AO approach for optimal aberration compensation.
  • the Hartmann-Shack wavefront sensor (HS-WS) 201 uses a lenslet array 215 and CCD camera 214 to sample the wavefront across the pupil.
  • a lens relay 211 and iris 216 are used in front of the HS-WS 201 to reduce reflection artifact from the cornea.
  • the predominant system aberrations are defocus and astigmatism, which can be corrected with either the woofer 254 w or the tweeter 254 t , but better corrected with the woofer because it constitutes a smaller fraction of its total range.
  • the system RMS error can be 0.64% (0.48 ⁇ m).
  • the Mirao requires a total surface stroke of ⁇ 1.5 ⁇ m to correct system aberrations.
  • the maximum stroke needed over the entire 33-deg. field for system aberration is ⁇ 4 ⁇ m.
  • the LSO module 205 includes a source 225 , a lens 211 and a cylindrical lens 235 to form a line of light.
  • An aperture splitter 236 can pick off light returning from the eye so it can be directed to a linear detector through a series of objective lens 230 .
  • a scanner 217 / 220 scans the imaging beam in the line focus configuration along the retina in a second dimension and descans the second light returning from the eye in the second dimension.
  • the LSO provides a wide field ( ⁇ 33 deg.) confocal view of the retina for scan placement and initial target identification.
  • the retinal tracker (RT) hardware can be fully integrated into the AO beam path to provide optimal tracking performance.
  • the active retinal tracker operates by directing and dithering (at 16 kHz) a beam onto a retinal target (usually the bright lamina cribrosa in the optic nerve head) and sensing with a confocal reflectometer phase shifts when the eye moves the target off the dither circle.
  • the resultant error signals are fed back in high speed closed loop fashion into two transverse galvanometers to maintain lock.
  • the retinal tracker configuration includes an FPGA-based tracking control board, which performs digital lock-in amplification and other signal processing for robust operation.
  • the tracking system maintains lock with a bandwidth greater than 1 kHz (limited only by the galvanometer inertial constraints) and an accuracy ⁇ 15 ⁇ m.
  • the RT module 206 includes a dual source 225 , focusing lens 211 , an aperture splitter 236 , and a resonant scanner 238 .
  • the fluorescence channel 202 channel includes source 218 and a lens 211 for delivering fluorescence excitation beam 241 and lens 211 , pinhole 209 , filter 239 and PMT 222 for collecting fluorescence emission beam 242 .
  • the 1- ⁇ m swept source for OCT imaging can have an average output power of 11 mW, a bandwidth (BW) of 79 nm centered at ⁇ 1070 nm, and a duty cycle of 0.65. This bandwidth has a theoretical axial resolution of 4.6 ⁇ m in tissue.
  • the wavelength of the OCT illumination beam can be selected to match a physical property of the tissue being imaged. The wavelength can be from 400 nm to about 2.6 microns, although longer or shorter wavelengths can be used depending on the chromophore.
  • Exemplary features to target include the retina or a portion of the retina, blood, retinal pigment epithelial (RPE) cells, a feeder vessel, a drusen, a small tumor, a microaneurysm, or an epiretinal membrane.
  • RPE retinal pigment epithelial
  • a wavelength of 680 nm can be used to monitor blood flow in the retina.
  • An OCT illumination wavelength of 1 micron has certain advantages over 850 nm illumination, including in penetration depth into the retina. Choroid and sclera can be imaged. 1 micron scatters less than 850 nm in the eye. Other wavelengths can be used to target or match the optical or light tissue interaction properties of specific layers, cells, organelles or molecules in the retina.
  • All other illumination sources are superluminescent diodes (SLD) that reduce image speckle and tracker noise.
  • SLO illumination beam centered at ⁇ 750 nm (14 nm BW) also acts as the wavefront sensor beacon.
  • the LSO illumination beam is centered at 830 nm (26 nm BW) and the tracker beam is centered at ⁇ 915 nm.
  • All sources are combined with off-the-shelf dichroic beamsplitters except for D2, which can be custom made to transmit both the 1- ⁇ m OCT and 750-nm SLO NIR beams while reflecting the 830-nm LSO and 915-nm RT beams.
  • D2 off-the-shelf dichroic beamsplitters
  • the OCT/SLO scan engine is configured to use a resonant scanner (RS) and single galvanometer for SLO imaging and two galvanometers for OCT imaging.
  • the OCT scan (line, circle, raster, radial, etc.) can be translated and centered anywhere in the wide field of the AO beam path by adjusting offset voltages to the galvanometers.
  • the SLO flying spot raster scan can be centered and shifted anywhere in the AO beam path for acquisition of montages and strips.
  • the x-axis OCT galvanometer serves the dual function of shifting the SLO raster in this mode.
  • the imaging system shown in FIG. 3 includes various beamsplitters, lens, minors and optics for coupling the various modules so that measurements can be taken.
  • Beamsplitters include pellicle beamsplitter 213 and dichroic beamsplitters 217 .
  • Turning minors 212 can be used to fold the optical design.
  • Spherical minors 219 can be used to provide a wide field of view.
  • the imaging system can include a LCD-based fixation target 237 .
  • the imaging system can include an optical component (such as a flip mount) 210 for an animal port.
  • FIG. 4 shows a schematic diagram of scanning axes for the SLO and OCT.
  • the SLO flying spot raster is created from the fast axis of scanner 1 and the slow axis of scanner 2 .
  • the OCT line or rater is created from the fast axis of scanner 2 and the slow axis of scanner 3 .
  • Each scanner can be a galvanometer or other scanning optic known in the art.
  • Scanner 3 can be used to create OCT raters or SLO montages or mosaics (e.g., stitching several high-resolution, low field images together to create a single high-resolution high-field image.
  • FIG. 5 show an example of an instrumentation layout.
  • box 300 represents the host computer
  • box 301 represents the instrumentation rack
  • box 302 represents the optical table.
  • the host computer 300 includes framegrabbers 122 for acquiring images and USB ports 307 for the DM controllers.
  • All system instrumentation can be contained in two electronics boxes—a tracker box 308 and an imaging box 309 .
  • the tracker box 308 contains the LSO/RT sources, the tracking RS pair, all the system galvanometers, and two custom electronic boards designed to control the retinal tracker in a high bandwidth closed loop manner.
  • the custom track controller board is an FPGA-based real-time processor that controls all hardware, generates all timing and waveform signals and performs the high-speed closed-loop feedback control.
  • the custom tracking motherboard (MB) 310 can be designed so that all off-the-shelf OEM electronic driver boards can be plugged into the system with minimal wiring.
  • the RT control board, OEM resonant scanner and galvanometer boards plug into the MB, which can include an integrated detector and driver/thermo-electric coolers for 2 SLDs.
  • the imaging box 309 contains the real time OCT digitizer and processing board, the SLO source and voltage-controlled RS driver board, and OCT depth stage controller.
  • the RS amplitude (which sets the SLO size) is controlled via the host computer with an analog waveform output from a USB DAQ.
  • the OCT image processing chain can be processed using a graphical processor unit (GPU) on a standard video card.
  • GPU graphical processor unit
  • a switch directs either the RS or swept source sync signals to the high speed digitizer. Both are TTL signals in the kHz range.
  • the digitizer generates a pixel clock (50 MHz), duplicates the line sync, and generates a frame sync signal, which is passed to the framegrabbers via the real time OCT processing board.
  • the real time processing board generates all the waveforms to drive the galvanometers.
  • the signal from the balanced detector generated from the fiber interferometer is input to the high speed digitizer. This signal is not used in SLO mode. Communication between the digitizer, real time OCT processing board, and framegrabbers is accomplished with the CameraLink interface.
  • the hardware used to control the multimodal AO system also includes three framegrabbers (one dual camera), two cameras, two detectors, four sources, five galvanometers, 3 resonant scanners, a motorized stage, and two deformable minors.
  • the custom SLO timing board includes functionality for non-linear pixel clock generation for real-time image de-warping from the sinusoidal resonant scanner drive signal; electronic blanking (clamping) with a high-speed multiplexor for real-time analog signal conditioning; x-y galvanometer waveform generation; resonant scanner amplitude signal generation; dual channel operation for simultaneous reflectance/fluorescence analog signal conditioning; and synchronization with the real-time SDOCT processing board.
  • the multimodal AO retinal imager was tested in six subjects to demonstrate performance capabilities.
  • the subjects were aged between 23 and 53 years and the refractive error was between 0 and 7D (all myopes).
  • a human subject protocol was approved by New England IRB prior to all imaging. All subjects gave informed consent to be imaged. Some of the subjects with small pupils were dilated to enhance AO correction. Subjects that were not dilated often had larger variability in AO and imaging performance, especially when imaging the fovea, which caused the pupil to constrict. All subjects used a bite bar for head stabilization and pupil centration.
  • the imaging sessions did not follow a set protocol but included OCT cross-sectional and raster scans (1-3 mm), SLO images (1- and 2-deg. fields), strip scans, and montages.
  • the montage scans step the SLO offset galvanometers over a matrix with overlap, the size of which (2 ⁇ 2, 3x3, 4 ⁇ 4, etc.) is configured by the user.
  • the SLO strip scanning is an innovation whereby the SLO offset galvanometers are slowly scanned in the horizontal or vertical direction to pan across a retinal patch and produce a stack of images that are significantly overlapping. This aids in automated registration, especially in the presence of excessive eye motion.
  • the system optical performance was characterized first using diffusely reflecting targets at various retinal (i.e., focal) conjugates. Next, the system and AO performance were tested using a model eye consisting of a 25-mm focal length (fl) achromat and a diffusely reflecting “retina.” Finally, the AO correction performance was measured in live human eyes.
  • fl focal length
  • the woofer corrected system In initial human subject testing of the dual-DM approach, a control algorithm was used whereby the woofer corrected system, large amplitude and/or low-order sample aberrations and the tweeter corrected small amplitude and/or high-order sample aberrations.
  • the woofer was initiated first and run in static mode where it could correct the wavefront for a fixed number of cycles and then held while the tweeter was activated after the woofer was frozen and left in dynamic mode.
  • the number of static cycles chosen is critical to insure proper lower-order aberration correction.
  • both DMs were used although the tweeter corrected only a very small amount of residual aberration.
  • the validation at retinal conjugates and in the model eye was performed by direct measurement of the point spread function (PSF) independent of the HS-WS at a plane conjugate to the SLO detector pinhole using a standard USB CCD camera.
  • the magnification from the SLO confocal pinhole (and CCD position) to the retina is ⁇ 9.25 so a 100-1 ⁇ m pinhole projects to roughly 11 ⁇ m on the retina, or ⁇ 2.2 times the 4.9-1 ⁇ m Airy disc at 750 nm.
  • a 200-1 ⁇ m pinhole ( ⁇ 22 ⁇ m on the retina) is less confocal allowing more scattered and aberrated light without improving imaging, while a 50-1 ⁇ m pinhole (5.4 ⁇ m on the retina) is tightly confocal: only 1.1 times the Airy disc.
  • images are first taken with the 100- ⁇ m pinhole, and the 50-1 ⁇ m pinhole is used for increased contrast in subjects with bright macula and the 200-1 ⁇ m pinhole is used for undilated subjects and subjects with dim macula.
  • the PSFs at retinal conjugates two and four (see FIG. 3 ) for focused illumination are shown in the first three columns in FIG. 6 .
  • the system aberration is minimal at r2, with some residual astigmatism.
  • the PSF FWHM full width half maximum, average of x and y
  • the PSF FWHM nearly doubles to ⁇ 152 ⁇ m without AO correction.
  • the PSF FWHM is 83 ⁇ m, less than two times the Airy disc size.
  • FIG. 6 also shows the PSFs in a model eye with and without AO correction (columns 4-5).
  • AO correction both DMs activated
  • the FWHM decreases to ⁇ 127 from 243 ⁇ m.
  • the CCD may have been slightly saturated, causing a slight overestimation of the PSF width).
  • Some residual astigmatism remains, but AO significantly improves the PSF approximately to the size of the confocal pinhole.
  • AO correction reduced the RMS error from ⁇ 0.6 ⁇ m to ⁇ 0.05 ⁇ m and increased the Strehl ratio to 0.92 (as measured by the wave aberration function from the HS-WS).
  • FIG. 7 An example of the AO performance achieved in one human subject is shown in FIG. 7 . Shown are the wavefront error map (top row) and the PSF (second row) for three cases: no AO correction (first column), DM1 (woofer) correction (second column), and dual-DM (woofer-tweeter) correction (third column). The time course of the correction and the aberrations separated by Zernike order are also shown.
  • the average RMS wavefront error (Strehl ratio) for the three cases was 1.215 ( ⁇ 0.01), 0.097 (0.52), and 0.052 (0.83) ⁇ m, respectively.
  • the dual-DM approach achieved more optimal AO correction in human subjects than could be achieved with a single mirror alone.
  • Examples from 4 of the 6 subjects in each of the three primary imaging modes are shown in FIG. 8 .
  • the LSO image provides a 33 deg. wide field view of the retina.
  • the 2-deg. SLO images were taken near the fovea.
  • Cone photoreceptors can be resolved to within ⁇ 0.5 deg. (100-150 ⁇ m) of the fovea.
  • the cross-sectional OCT image spans 2 mm (6.9 deg.) centered on the fovea.
  • the OCT images are composites of between 5 and 10 frames after flattening and alignment.
  • Ten major retinal layers (nerve fiber, ganglion cell, inner plexiform, inner nuclear, outer plexiform, outer nuclear, inner segments, outer segments, retinal pigment epithelium, choriocapillaris) can be resolved.
  • FIG. 9 shows single and 4-frame average cross-sectional FDOCT images through the fovea for one subject that was imaged with both an 850-nm spectrometer-based instrument and the current 1050-nm swept source-based AO-FDOCT imager.
  • the axial resolution in the former was better (theoretical axial resolution: 3.6 ⁇ m vs. 4.6 ⁇ m), the improved penetration into the choroid is clear.
  • FIG. 10 An AOSLO montage in the central ⁇ 3 deg. for one subject is shown in FIG. 10 .
  • the montage was created by stitching together a 3 ⁇ 3 matrix of 2-deg. AOSLO images.
  • the magnified regions to the right indicate excellent cone contrast within 0.5 deg. ( ⁇ 150 ⁇ m) of the fovea center.
  • strip scan and strip montage image scanning procedures can be used to map structures (e.g., photoreceptors) across the macula or retinal region.
  • a montage or mosaic image can be created using a scanning device of the imaging apparatus (e.g., the third scanning device 38 shown in FIG. 1 or a scanner 220 shown in FIG. 3 ).
  • the scanning device includes a scanner and a driver.
  • the scanner can be a resonant scanner that scans a first portion of the eye (e.g., a first portion of the retina) and the driver can be a galvanometer that repositions the resonant scanner on a second portion of the eye (e.g., a second portion of the retina) according to a predetermined off-set.
  • a first image (e.g., image) can be acquired by the imaging apparatus when the resonant scanner scans the imaging beam along on the first portion of the eye.
  • the scan can be a raster scan or a two-dimensional transverse scan.
  • a second image (e.g., image) can be acquired by the imaging apparatus after the galvanometer repositions the scanner on the second portion of the eye. The process can be repeated to acquire images over the other portions of the eye until the montage has been generated.
  • An exemplary procedure for recording montage or mosaic images is described in U.S. Pat. No. 7,758,189, the disclosure of which is herein incorporated by reference in its entirety.
  • the automated registration algorithm co-aligns multiple frames for averaging (to increase SNR), for quantification of large retinal patches in the presence of intra-frame warping, to determine the shift in a secondary imaging mode where SNR is extremely low (i.e., fluorescence), or as a precursor to stitching montages or strips together.
  • SNR extremely low
  • the algorithm aligns by horizontal strips 10 pixels wide. This makes the registered image more impervious to torsional eye motion that can cause intra-frame warping.
  • a stack of AOSLO images taken for the challenging case of high image uniformity (and lack of high contrast vessel targets) in the foveal avascular zone were aligned.
  • FIG. 11 shows the results compared to no registration and registration frame-by-frame.
  • FIG. 12 shows a registered stack of multimodal AO images from a slow strip scan in the presence of above average eye movements (for a control subject).
  • Cone photoreceptor counts were performed on several retinal patches at various eccentricity from a single 2-deg. AOSLO scan near the fovea (identifiable in the images) for 4 subjects using manual and automated methods ( FIG. 13 ).
  • the automated cone photoreceptor counting algorithm corrects for a non-uniform image background, applies morphological operators, and uses a centroiding algorithm for initial identification of cone locations. The locations are then filtered to provide a final cone count in the retinal patch examined. The final filter parameter is set according to the eccentricity and so requires some limited user input.
  • the manual (solid symbols) and automated (open symbols) results are compared to previously reported histology. In general, the automated result showed good correspondence with the manual counts and histology. For lower eccentricities close to the resolution limit of the instrument, the algorithm begins to break down and underestimate the count.
  • FIG. 14 shows an example of the AO performance achieved in one human subject.
  • Three images are shown: SLO (1 deg. field, top row), WS (second row), and PSF (third row) for three cases: no AO correction (third column), static DM1 (woofer) correction (second column), and dual-DM correction (first column) with both static DM1 (woofer) and dynamic DM2 (tweeter).
  • SLO deg. field, top row
  • WS second row
  • PSF third row
  • no AO correction third column
  • static DM1 woofer
  • dual-DM correction first column
  • Both minors are important to achieve the best possible AO correction in human subjects.
  • the multimodal AO system can be configured to acquire images from the SLO and OCT channels sequentially while the LSO, AO, HS-WS, and RT are all running continuously. This can be done in a unique configuration whereby the real time OCT processing board that drives the galvos can accept input from either the SLO RS or the OCT swept source.
  • the multiple scanning schemes available for both modes (OCT line and raster, SLO raster, montages, strip scans, etc.) use all the same hardware (scanners, real time processing board) and are set up from an extremely intuitive and flexible user interface.
  • Another multimodal AO retinal imaging system can include simultaneous SLO and OCT imaging, but it uses a spectrometer-based FDOCT channel. Thus, for some applications that target deeper structures and vasculature, the enhanced depth penetration with 1-1 ⁇ m illumination takes precedence over simultaneous OCT/SLO imaging.
  • a suite of post-processing analysis routines for both SLO and OCT images have been developed.
  • the functionality of these algorithms include registration, image averaging, montage and strip stitching, photoreceptor quantification, photoreceptor density mapping, and segmentation (retinal layer and drusen).
  • Some algorithms require limited user input (i.e., are semi-automated) while others operate in a fully automated manner (e.g., photoreceptor counting). With the multimodal image acquisition modes and these analysis tools, it is now possible to fully map retinal layers and critical structures across the entire macula.
  • FIG. 15 shows an exemplary SLO timing board functional schematic.
  • the SLO timing board can include a FPGA-based design to provide further device automation and enhanced performance (e.g., increase SNR from a stable blanking region).
  • the functionality of the timing board can include generation of a non-linear pixel clock for automatic SLO image dewarping, automatic electronic video blanking via high speed analog signal multiplexing, generation of SLO/OCT waveforms and offsets (user-controlled), generation of the SLO resonant scanner amplitude control signal (user-controlled), and/or dual channel video operation that can be coupled to simultaneous reflectance/fluorescence imaging.
  • the SLO timing board includes a TTL reference signal 400 , a digital PLL chip 401 , a non-linear pixel clock signal 402 , a resonant scanner driver 403 , a two-channel digital-to-analog converter 404 , an RS drive signal 405 , an OCT/SLO scanner drive waveforms 406 , a four-channel digital-to-analog converter 407 , a RS-232 port for host computer communication 408 , a field programmable gated array chip 409 , framegrabber ports 410 , a high speed video multiplexor 412 , and a SLO image showing blanking region 413 .
  • the above-described techniques can be implemented in digital electronic circuitry, or in computer hardware, firmware, software, or in combinations of them.
  • the implementation can be as a computer program product, i.e., a computer program tangibly embodied in an information carrier, e.g., in a machine-readable storage device or in a propagated signal, for execution by, or to control the operation of, data processing apparatus, e.g., a programmable processor, a computer, or multiple computers.
  • a computer program can be written in any form of programming language, including compiled or interpreted languages, and it can be deployed in any form, including as a stand-alone program or as a module, component, subroutine, or other unit suitable for use in a computing environment.
  • a computer program can be deployed to be executed on one computer or on multiple computers at one site or distributed across multiple sites and interconnected by a communication network.
  • Method steps can be performed by one or more programmable processors executing a computer program to perform functions of the technology by operating on input data and generating output. Method steps can also be performed by, and apparatus can be implemented as, special purpose logic circuitry, e.g., a FPGA (field programmable gate array), a FPAA (field-programmable analog array), a CPLD (complex programmable logic device), a PS oC (Programmable System-on-Chip), ASIP (application-specific instruction-set processor), or an ASIC (application-specific integrated circuit), or the like.
  • Subroutines can refer to portions of the stored computer program and/or the processor, and/or the special circuitry that implement one or more functions.
  • processors suitable for the execution of a computer program include, by way of example, both general and special purpose microprocessors, and any one or more processors of any kind of digital computer.
  • a processor will receive instructions and data from a read-only memory or a random access memory or both.
  • the essential elements of a computer are a processor for executing instructions and one or more memory devices for storing instructions and data.
  • a computer will also include, or be operatively coupled to receive data from or transfer data to, or both, one or more mass storage devices for storing data, e.g., magnetic, magneto-optical disks, or optical disks. Data transmission and instructions can also occur over a communications network.
  • Information carriers suitable for embodying computer program instructions and data include all forms of non-volatile memory, including by way of example semiconductor memory devices, e.g., EPROM, EEPROM, and flash memory devices; magnetic disks, e.g., internal hard disks or removable disks; magneto-optical disks; and CD-ROM and DVD-ROM disks.
  • semiconductor memory devices e.g., EPROM, EEPROM, and flash memory devices
  • magnetic disks e.g., internal hard disks or removable disks
  • magneto-optical disks e.g., CD-ROM and DVD-ROM disks.
  • the processor and the memory can be supplemented by, or incorporated in special purpose logic circuitry.
  • modules and “function,” as used herein, mean, but are not limited to, a software or hardware component which performs certain tasks.
  • a module may advantageously be configured to reside on addressable storage medium and configured to execute on one or more processors.
  • a module may be fully or partially implemented with a general purpose integrated circuit (IC), DSP, FPGA or ASIC.
  • IC general purpose integrated circuit
  • a module may include, by way of example, components, such as software components, object-oriented software components, class components and task components, processes, functions, attributes, procedures, subroutines, segments of program code, drivers, firmware, microcode, circuitry, data, databases, data structures, tables, arrays, and variables.
  • the functionality provided for in the components and modules may be combined into fewer components and modules or further separated into additional components and modules.
  • the components and modules may advantageously be implemented on many different platforms, including computers, computer servers, data communications infrastructure equipment such as application-enabled switches or routers, or telecommunications infrastructure equipment, such as public or private telephone switches or private branch exchanges (PBX).
  • data communications infrastructure equipment such as application-enabled switches or routers
  • telecommunications infrastructure equipment such as public or private telephone switches or private branch exchanges (PBX).
  • PBX private branch exchanges
  • the above described techniques can be implemented on a computer having a display device, e.g., a CRT (cathode ray tube) or LCD (liquid crystal display) monitor, for displaying information to the user and a keyboard and a pointing device, e.g., a mouse or a trackball, by which the user can provide input to the computer (e.g., interact with a user interface element).
  • a display device e.g., a CRT (cathode ray tube) or LCD (liquid crystal display) monitor
  • a keyboard and a pointing device e.g., a mouse or a trackball
  • Other kinds of devices can be used to provide for interaction with a user as well; for example, feedback provided to the user can be any form of sensory feedback, e.g., visual feedback, auditory feedback, or tactile feedback; and input from the user can be received in any form, including acoustic, speech, or tactile input.
  • the above described techniques can be implemented in a distributed computing system that includes a back-end component, e.g., as a data server, and/or a middleware component, e.g., an application server, and/or a front-end component, e.g., a client computer having a graphical user interface and/or a Web browser through which a user can interact with an example implementation, or any combination of such back-end, middleware, or front-end components.
  • the components of the system can be interconnected by any form or medium of digital data communication, e.g., a communication network. Examples of communication networks include a local area network (“LAN”) and a wide area network (“WAN”), e.g., the Internet, and include both wired and wireless networks. Communication networks can also all or a portion of the PSTN, for example, a portion owned by a specific carrier.
  • LAN local area network
  • WAN wide area network
  • Communication networks can also all or a portion of the PSTN, for example, a portion owned
  • the computing system can include clients and servers.
  • a client and server are generally remote from each other and typically interact through a communication network.
  • the relationship of client and server arises by virtue of computer programs running on the respective computers and having a client-server relationship to each other.

Landscapes

  • Health & Medical Sciences (AREA)
  • Life Sciences & Earth Sciences (AREA)
  • Biomedical Technology (AREA)
  • Heart & Thoracic Surgery (AREA)
  • Veterinary Medicine (AREA)
  • Biophysics (AREA)
  • Ophthalmology & Optometry (AREA)
  • Engineering & Computer Science (AREA)
  • Public Health (AREA)
  • Physics & Mathematics (AREA)
  • Medical Informatics (AREA)
  • Molecular Biology (AREA)
  • Surgery (AREA)
  • Animal Behavior & Ethology (AREA)
  • General Health & Medical Sciences (AREA)
  • Nuclear Medicine, Radiotherapy & Molecular Imaging (AREA)
  • Radiology & Medical Imaging (AREA)
  • Eye Examination Apparatus (AREA)

Abstract

An optical apparatus includes a system of optical components capable of operating in a scanning laser ophthalmoscope (SLO) mode and an optical coherence tomography (OCT) mode. The system of optical components includes a first optical module for the SLO mode, a second optical module for the OCT mode, and a first scanning device. The first optical module for the SLO mode includes a first source adapted to provide a first imaging beam for the SLO mode and a first detection device configured to receive a first signal associated with a first image of a retina of an eye. The second optical module for the OCT mode includes a second source adapted to provide a second imaging beam for the OCT mode and a second detection device configured to receive a second signal associated with a second image of the retina. The first scanning device is configured to move the first imaging beam along the retina in the slow axis of the SLO mode to acquire the first image and (ii) to move the second imaging beam along the retina in the fast axis of the OCT mode to acquire the second image.

Description

    CROSS REFERENCE TO RELATED APPLICATION
  • This application is a continuation of U.S. Ser. No. 13/011,404, filed Jan. 21, 2011, which claims the benefit of and priority to U.S. Provisional Patent Application No. 61/297,128 filed Jan. 21, 2010, which are both owned by the assignee of the instant application and the disclosures of which are incorporated herein by reference in their entirety.
  • GOVERNMENT RIGHTS
  • The invention was made with government support under NIH National Eye Institute grant no. 1R43EY018986-01. The government may have certain rights in the invention.
  • FIELD OF THE INVENTION
  • The invention relates generally to retinal imaging, and more particularly, to a multi-functional retinal imaging system that combines adaptive optics corrected optical coherence tomography and scanning laser ophthalmoscopy channels.
  • BACKGROUND
  • Adaptive optics (AO) and optical coherence tomography (OCT) can provide information on cellular and sub-cellular structures in the live eye. OCT uses low-coherence interferometry to de-link axial resolution from the diffraction-limited depth-of-field for generation of micron-level axial resolution optical depth sections. AO is a technique to enhance the transverse resolution and depth sectioning capabilities by detection and correction of ocular aberrations. It has been integrated into instruments for full-field fundus imaging, scanning laser ophthalmoscopy (SLO), and Fourier domain (FD) OCT.
  • AO has also become a staple for vision researchers as a tool to explore the structural and functional aspects of vision and its disruption by disease. While AO has yet to make a full transition from research lab to clinic, OCT is now a standard diagnostic procedure for glaucoma, macular holes, macula edema, retinal detachments, and other retinal pathologies. FDOCT has now supplanted time domain(TD) OCT because of its advantages of higher speeds (near video rate), higher signal-to-noise ratio via simultaneous multiplexed acquisition of depth voxels, and lower phase noise. Clinical FDOCT systems are available commercially from several companies.
  • FDOCT comes in two basic varieties depending upon whether the source arm (swept source, SS) or the detection arm (spectral domain, SD) of the interferometer is altered. Each technique has advantages and disadvantages, but in general, SDOCT systems have slightly better axial resolution and SSOCT systems have increased depth range and accessibility to longer wavelengths. Ophthalmic OCT research systems at 1 μm, including initial reports configured with AO have shown significantly improved choroidal penetration compared to 850 nm systems. In addition to increased penetration, ocular dispersion is less at 1 μm than at 850 nm.
  • SLO and OCT are complementary tools for imaging the retina. OCT is an interferometric technique, whose fast 2-D frame axis is cross-sectional (i.e., lateral-axial) with micron level axial resolution that yields excellent sectioning capability. OCT is therefore better suited for visualization of retinal layers. SLO is a confocal technique whose fast 2-D frame axis is en-face (i.e. lateral-lateral) with sensitivity to multiply-scattered light. SLO is therefore better able to resolve photoreceptors, blood flow, and capillaries with higher contrast than OCT. Also, SLO systems can be configured to collect fluorescence signals.
  • SUMMARY OF THE INVENTION
  • The invention, in one embodiment, features a multi-functional retinal imager that combines adaptive optics-corrected Fourier domain optical coherence tomography and scanning laser ophthalmoscopy channels. The adaptive optics provide high lateral resolution and a narrow depth of focus by real-time correction of ocular aberrations that distort the wavefront and blur the focused beam in the eye. OCT is a technique for micron-level axial resolution and depth sectioning. The technology can include both spectrometer-based and swept source-based FDOCT implementations. A wide field line scanning ophthalmoscope (LSO) and a retinal tracker (RT) can also be included in the system. In certain embodiments, a retinal imaging system can combine AO-corrected scanning laser ophthalmoscopy, swept source Fourier domain optical coherence tomography imaging, and wide field line scanning ophthalmoscopy imaging modes, and retinal tracking in a single, compact clinical platform.
  • In one aspect, the technology features an optical apparatus including a system of optical components capable of operating in a scanning laser ophthalmoscope (SLO) mode and an optical coherence tomography (OCT) mode. The system of optical components includes a first optical module for the SLO mode, a second optical module for the OCT mode, and a first scanning device. The first optical module for the SLO mode includes a first source adapted to provide a first imaging beam for the SLO mode and a first detection device configured to receive a first signal associated with a first image of a retina of an eye. The second optical module for the OCT mode includes a second source adapted to provide a second imaging beam for the OCT mode and a second detection device configured to receive a second signal associated with a second image of the retina. The first scanning device is configured to move the first imaging beam along the retina in the slow axis of the SLO mode to acquire the first image and (ii) to move the second imaging beam along the retina in the fast axis of the OCT mode to acquire the second image.
  • In another aspect, there is a method of imaging a retina of an eye. The method includes acquiring a SLO image of the eye by receiving, on a first detector, a first light returning from the eye and providing a first electrical signal responsive to the first light at each of a plurality of locations along the first detector. The first electrical signal is indicative of the SLO image of the eye. The method includes acquiring an OCT image of the eye by receiving, on a second detector, a second light returning from the eye and providing a second electrical signal responsive to the second light at each of a plurality of locations along the second detector. The second electrical signal is combined with a reference signal from a reference arm. The second electrical signal and the reference signal are associated with the OCT image of the eye. The method also includes scanning, using a first scanning device, (i) a first imaging beam along the retina in the slow axis of the SLO mode to acquire the SLO image and (ii) a second imaging beam along the retina in the fast axis of the OCT mode to acquire the OCT image.
  • In yet another aspect, there is an optical apparatus including a system of optical components capable of operating in a scanning laser ophthalmoscope (SLO) mode and an optical coherence tomography (OCT) mode. The system of optical components includes at least two spherical minors, at least two deformable minors (DM's) positioned behind the at least two spherical minors, a beamsplitter positioned behind the at least two deformable minors, an OCT optical module introduced by the beamsplitter, and a SLO optical module behind the beamsplitter. Each spherical minor has a diameter greater than 20 cm and is positioned relative to the eye. The optical apparatus also includes first, second and third scanning devices. The first scanning device is positioned between the beamsplitter and the eye. The first scanning device is configured (i) to move a first imaging beam along the retina in the slow axis of the SLO mode to acquire an SLO image and (ii) to move a second imaging beam along the retina in the fast axis of the OCT mode to acquire an OCT image. The second scanning device is positioned behind the beamsplitter. The second scanning device is configured to move the first imaging beam along the retina in the fast axis of the SLO mode to acquire the SLO image. The third scanning device is positioned between the beamsplitter and the eye. The third scanning device is configured to move the second imaging beam along the retina in the slow axis of the OCT mode to acquire the OCT image.
  • In other examples, any of the aspects above, or any apparatus, system or device, or method, process or technique, described herein, can include one or more of the following features. In various embodiments, the OCT mode can include a Fourier domain OCT channel configured to be spectrometer-based or swept source-based. The system of optical components can be adapted to simultaneously image the same retinal coordinates in the SLO mode and OCT module.
  • In certain embodiments, the optical apparatus includes a second scanning device configured to move the first imaging beam along the retina in the fast axis of the SLO mode to acquire the first image and a third scanning device configured to move the second imaging beam along the retina in the slow axis of the OCT mode to acquire the second image. The first scanning device, the second scanning device and the third scanning device can be positioned at pupil conjugates in the system of optical components. The first scanning device can be mounted to the third scanning device at a pupil conjugate.
  • In various embodiments, the second imaging beam of the OCT mode is introduced by a beamsplitter positioned between the eye and the SLO module. The third scanning device can be configured to scan the first imaging beam to generate a mosaic image of the eye.
  • In some embodiments, a third optical module is configured to (i) detect an optical distortion and (ii) correct the optical distortion in at least one of the first or second imaging beams scanned on the eye. The third optical module can include a wavefront sensor adapted to detect the optical distortion and a wavefront compensator adapted to correct the optical distortion in the first or second imaging beam. In certain embodiments, two wavefront compensators are positioned between the beamsplitter and the eye. A dual-deformable minor configuration can be used to provide simultaneous, high-fidelity, wide dynamic range correction of lower- and higher-order ocular aberrations.
  • A fourth optical module can be configured to operate in a line scanning ophthalmoscope (LSO) mode. The fourth optical module can include a third source adapted to provide a third imaging beam in a line focus configuration for the LSO mode. The fourth optical module can be configured to (i) scan the third imaging beam in the line focus configuration along the retina in a second dimension and (ii) descan the second light returning from the eye in the second dimension. The light returning from the eye is directed to a third detection device.
  • The system of optical components can include a fifth optical module adapted to track a reference feature of the retina of the eye. The first optical module can be adapted to control the position of the first imaging beam relative to the reference feature to correct for motion of the eye. The system of optical components can include a sixth optical module adapted to provide a fluorescence imaging channel. A LCD-based fixation target can be used to acquire images of the eye in at least one of the SLO mode, the OCT mode, or the LSO mode.
  • In various embodiments, the system of optical components includes at least two spherical mirrors. Each spherical mirror has a diameter greater than 20 cm. The spherical mirrors are positioned relative to the eye and configured to provide a field of view greater than 30 degrees. The wavelength of the second imaging beam of the OCT mode can be selected to match a physical property of the tissue.
  • The optical system can be used for one or more of the following applications:
      • Retinal layer quantification and mapping
      • Photoreceptor quantification and mapping
      • Retinal vasculature mapping
      • Retinal flow (FDOCT channel in Doppler mode)
      • Diagnosis and early detection of retinal diseases such as diabetic retinopathy (DR), age-related macular degeneration (AMD), retinitis pigmentosa (RP), and retinopathy of prematurity (ROP).
      • Drug development and determination of efficacy
      • Vision studies
      • Small animal imaging
  • Other aspects and advantages of the invention will become apparent from the following detailed description, taken in conjunction with the accompanying drawings, illustrating the principles of the invention by way of example only.
  • BRIEF DESCRIPTION OF THE DRAWINGS
  • The advantages of the invention described above, together with further advantages, may be better understood by referring to the following description taken in conjunction with the accompanying drawings. The drawings are not necessarily to scale, emphasis instead generally being placed upon illustrating the principles of the invention.
  • FIG. 1 shows a schematic diagram of an optical apparatus for imaging a retina of an eye.
  • FIG. 2 shows a block diagram of an exemplary multimodal AO system.
  • FIG. 3 shows an unfolded optical layout for a multimodal AO system.
  • FIG. 4 shows a schematic diagram of scanning axes for the SLO and OCT.
  • FIG. 5 show an example of an instrumentation layout.
  • FIG. 6 shows the point spread functions (PSF's) at retinal conjugates two and four for focused illumination.
  • FIG. 7 shows an example of the AO performance achieved in one human subject.
  • FIG. 8 shows examples from 4 of the 6 subjects in each of the three primary imaging modes (LSO, SLO, OCT).
  • FIG. 9 shows single and 4-frame average cross-sectional FDOCT images through the fovea for one subject that was imaged with both an 850-nm spectrometer-based instrument and the current 1050-nm swept source-based AO-FDOCT imager.
  • FIG. 10 shows an AOSLO montage in the central ˜3 deg. for one subject.
  • FIG. 11 shows the results compared to no registration and registration frame-by-frame.
  • FIG. 12 shows a registered stack of multimodal AO images from a slow strip scan in the presence of above average eye movements (for a control subject).
  • FIG. 13 shows cone photoreceptor counts on several retinal patches at various eccentricity from a single 2-deg. AOSLO scan near the fovea (identifiable in the images) for 4 subjects using manual and automated methods.
  • FIG. 14 shows an example of the AO performance achieved in one human subject.
  • FIG. 15 shows an exemplary SLO timing board functional schematic.
  • DESCRIPTION OF THE INVENTION
  • FIG. 1 shows an optical apparatus 10 including a system of optical components capable of operating in a scanning laser ophthalmoscope (SLO) mode and an optical coherence tomography (OCT) mode. The system of optical components includes a first optical module 14 for the SLO mode, a second optical module 18 for the OCT mode, and a first scanning device 22. The first optical module 14 for the SLO mode includes a first source adapted to provide a first imaging beam 24 for the SLO mode and a first detection device configured to receive a first signal associated with a first image of a retina 26 of an eye 30. The second optical module 18 for the OCT mode includes a second source adapted to provide a second imaging beam 32 for the OCT mode and a second detection device configured to receive a second signal associated with a second image of the retina 26. The first scanning device 22 is configured to move the first imaging beam along the retina 26 in the slow axis of the SLO mode to acquire the first image and to move the second imaging beam along the retina 26 in the fast axis of the OCT mode to acquire the second image.
  • The optical apparatus 10 can include a second scanning device 34 and a third scanning device 38. The second scanning device 34 can be configured to move the first imaging beam along the retina in the fast axis of the SLO mode to acquire the first image.
  • The third scanning device 38 can be configured to move the second imaging beam along the retina in the slow axis of the OCT mode to acquire the second image. The first scanning device 22, the second scanning device 34 and the third scanning device 38 can be positioned at pupil conjugates in the system of optical components. In certain embodiments, the first scanning device 22 is mounted to the third scanning device 38 at a pupil conjugate. The third scanning device 38 can be configured to scan the first imaging beam to generate a mosaic image of the eye.
  • A beamsplitter 42 can be used to introduce the second imaging beam of the OCT mode. The beamsplitter 42 can be positioned between the eye 30 and the SLO module 14. The optical apparatus 10 can include a third optical module configured to (i) detect an optical distortion and (ii) correct the optical distortion in at least one of the first or second imaging beams scanned on the eye. The third optical module can include a wavefront sensor 46 adapted to detect the optical distortion and at least one wavefront compensator 50 adapted to correct the optical distortion in the first or second imaging beam. In certain embodiments, a first wavefront compensator and a second wavefront compensator are positioned between the beamsplitter 42 and the eye 30.
  • The optical apparatus 10 can include at least two spherical minors 54. Each spherical minor 54 can have a large surface area. For example, each spherical mirror 54 can have a diameter greater than 20 cm. The spherical mirrors 54 can be positioned relative to the eye and configured to provide a field of view greater than 30 degrees. In some embodiments, the field of view is about 15 to 35 degrees. An advantage of the wide field front end is that the SLO and OCT scans can be made large. A user can perform an initial low resolution, large scan to map the entire macula and then perform a high resolution scan of specific targets.
  • FIG. 2 shows a block diagram of an exemplary multimodal AO system. The optical design can significantly reduce inherent aberrations providing a wide field of regard (for example, ˜33 degrees) for the SLO and SSOCT fields while fully integrating the LSO imaging and RT reflectometer. The AO components can include a Hartmann-Shack wavefront sensor (HS-WS) and two deformable minors in a woofer-tweeter configuration for high-fidelity, wide dynamic range correction of lower- and higher-order ocular aberrations. Other features of the system include a custom, FPGA-based OCT digitizer and processing board and a high resolution LCD-based fixation target. The design achieves an extremely compact instrument footprint suitable for clinical portability. The system performance was validated on model eyes and human and animal subjects.
  • FIG. 2 shows a LSO image 100, a HS-WS image 101, an AOSLO image 102 and FDOCT image 103. The imaging system shown in FIG. 2 can be used to image human eyes 240 or animals 104. The imaging system includes a first module/SLO channel 116, a second module/FDOCT channel (e.g., a spectrometer-based FDOCT channel 117 or a swept source based FDOCT channel 118), a third module/AO module 115, a fourth module/LSO channel 205, a fifth module/retinal tracker 206, and a sixth module/fluorescence channel 119.
  • The SLO channel 116 includes a source 225 (e.g., a superluminescent diode), a detection device 120 (e.g., a confocal detector), a SLO timing board 121, and a framegrabber 122. The FDOCT channel can be a spectrometer-based FDOCT channel 117 or a swept source based FDOCT channel 118 coupled to the optical system by a fiber connector 207.
  • Both FDOCT channels includes a framegrabber 122, a real-time FDOCT processor/controller 123, an optical delay line 125, and a fiber coupler 223. The SDOCT 117 utilizes a source 225 (e.g., a superluminescent diode) and a spectrometer 124. The SSOCT 118 utilizes a swept source 226, a high speed digitizer 128 and a balanced detector 227.
  • The third module/AO module 115 includes image scanners 110, at least one deformable mirror/wavefront compensator 111, a DM controller 112, a HS-WS 113, and a framegrabber 122.
  • The fourth module/LSO channel 205 includes a LSO module 250 and a framegrabber 122. The fifth module/retinal tracker 206 includes a tracker source and reflectometer 107, a tracker controller 108, and tracker scanners 109. An exemplary LSO system is described in U.S. Pat. No. 6,758,564, the disclosure of which is herein incorporated by reference in its entirety. The LSO can be combined with a retinal tracking system to form a TSLO. An exemplary tracking system is described in U.S. Pat. No. 5,797,941, the disclosure of which is herein incorporated by reference in its entirety. Stabilized retinal imaging with adaptive optics is described in U.S. Pat. No. 7,758,189, the disclosure of which is herein incorporated by reference in its entirety. A hybrid LSLO/OCT instrument is described in U.S. Pat. No. 7,648,242, the disclosure of which is herein incorporated by reference in its entirety. An adaptive optics line scanning ophthalmoscope is described in U.S. Patent Publication No. 2010/0195048, the disclosure of which is herein incorporated by reference in its entirety.
  • The sixth module/fluorescence channel 119 includes a fluorescence excitation beam 241, a fluorescence emission beam 242, a wavelength selection filter 239, a pre-amplifier 129, a photomultiplier tube (PMT) 130, and a framegrabber 122. The source can be any fluorescent source (e.g., white light, laser, SLD, LED, etc.) with sufficient power to excite the appropriate retinal fluorophores. The fluorescence channel can include dichroic beamsplitters to combine visible excitation and emission beam with NIR imaging beams and to separate excitation and emission beams. The filter 239 can be a barrier (notch) filter to remove all wavelengths except fluorescence on the PMT detector. A filter can be selected based on the desired fluorophore.
  • The imaging system shown in FIG. 2 includes various beamsplitters and optics for coupling the various modules so that measurements can be taken. Beamsplitters include pellicle beamsplitter 213 and dichroic beamsplitters 217. One skilled in the art will recognize that other optics can be used to couple the optical modules. Spherical mirrors 219 can be used to provide a wide field of view. The imaging system can include a LCD-based fixation target 237.
  • The imaging system can be configured to accommodate two or more output pupil sizes. For example, an optical component 210 can be used to couple a second optical imaging line to the instrument. In certain embodiments, the optical component is a flip mount. In some embodiments, this is desirable so that animals 104 can be imaged or so that humans with different pupil sizes can be imaged. An integrated small animal imaging port (accessed from a flip mounted minor) can change the pupil magnification for AO-correction in small animals, which have smaller dilated pupil sizes. The beam diameter at the output for two exemplary configurations is 7.5 and 2.5 mm. Smaller pupil sizes can provide for larger depth of focus. The optical component or the flip mount can be actuated manually or automatically by a motor controlled by software on a computer.
  • A wide field (>30 degree) optical design allows high resolution image field (typically 1-3 degrees) to be placed anywhere in the larger field of regard without re-positioning the patient or moving the fixation target. In certain embodiments, the field is about 15 to 35 degrees. With dynamic AO correction, variability in system aberrations across the wide field of regard can be compensated in real-time. Placing optical elements at pupil conjugates and introducing beams with dichroic beamsplitters allows simultaneous acquisition of AO-correct SLO and OCT images. The SLO resonant scanner is placed behind the DMs and the OCT beam is introduced with a dichroic beamsplitter between the resonant scanner and the DMs.
  • The HS-WS is acquired synchronously so that AO-correction is uniform across the SLO or OCT image field. The instrumentation is also can be designed so that the LSO image is acquired and the RT operates simultaneously. The SLO and OCT images can be registered (e.g., imaging same retinal coordinates).
  • A dual-DM configuration can provide simultaneous high-fidelity, wide dynamic range correction of lower- and higher-order ocular aberrations. This allows AO corrections to be applied to a broader clinical population. The lower-order aberrations (up to 5 Zernike orders) are corrected with a very high-stroke DM with a lower number of actuators. The higher order aberrations (up to 8 Zernike orders) are corrected with a high-actuator count DM with a lower stroke.
  • The optical system includes an integrated LSO/RT optical head and beam path. The optics and instrumentation are slightly less complex with the fully integrated LSO/RT beam paths. This is made possible by the wide field optical design. The LSO and RT beams are typically at different wavelengths than the SLO and OCT beams.
  • FIG. 3 shows an unfolded optical layout. All imaging modes access a common beam path comprised of all-reflective optical elements to minimize chromatic aberrations and maintain high throughput. Ten spherical minors 219 are used to transfer and magnify (or minify) the retinal and pupil planes to successive conjugates. The magnification of each relay is set to nearly fill the physical dimensions of each component. All scanners and DMs are placed at pupil conjugates to pivot about and correct at a single plane. The tracking galvanometers are placed at conjugates to the eye's center-of-rotation to simultaneously track retinal and pupil shifts.
  • The SLO channel 200 utilizes a confocal pinhole 209 and an avalanche photodiode (APD) 208 to collect light returning from the retina and source 225.
  • The OCT channel can be configured in a spectrometer based 203 or a swept source-based 204 architecture. Both architectures can be fiber connected 207 to the main optical line by a dichroic beamsplitter 217, a lens 211 and an achromatizer 234. The spectrometer based OCT 203 utilizes a source 225, a circulator 224 fiber connected 207 to a detection device including a lens 211, a transmission grating 229, a series of objective lenses 230, and a linear detector 233. The SDOCT 203 also includes a polarization controller 221 and a 2×2 fiber coupler 223 fiber connected 207 to an optical delay line including a lens 211, dispersion compensation cube 232, a neutral density filter 231 and mirrors 228. The optical delay line uses a folded arrangement—five passes off the mirrors 228- to match the ˜4.3 m sample pathlength.
  • The swept source-based OCT 204 utilizes a swept source 226, a circulator 224 connected to a balanced detector 227 and a fiber coupler 223. The SSOCT 204 includes a polarization controller 221 and an optical delay line. The balanced detector provides efficient light collection and common mode signal rejection.
  • The AO design includes a dual minor 254 (e.g., woofer 254 w and tweeter 254 t) AO approach for optimal aberration compensation. The Hartmann-Shack wavefront sensor (HS-WS) 201 uses a lenslet array 215 and CCD camera 214 to sample the wavefront across the pupil. A lens relay 211 and iris 216 are used in front of the HS-WS 201 to reduce reflection artifact from the cornea. The predominant system aberrations are defocus and astigmatism, which can be corrected with either the woofer 254 w or the tweeter 254 t, but better corrected with the woofer because it constitutes a smaller fraction of its total range. The system RMS error can be 0.64% (0.48 μm). The Mirao requires a total surface stroke of ˜1.5 μm to correct system aberrations. The maximum stroke needed over the entire 33-deg. field for system aberration is <4 μm.
  • The LSO module 205 includes a source 225, a lens 211 and a cylindrical lens 235 to form a line of light. An aperture splitter 236 can pick off light returning from the eye so it can be directed to a linear detector through a series of objective lens 230. A scanner 217/220 scans the imaging beam in the line focus configuration along the retina in a second dimension and descans the second light returning from the eye in the second dimension. The LSO provides a wide field (−33 deg.) confocal view of the retina for scan placement and initial target identification.
  • The retinal tracker (RT) hardware can be fully integrated into the AO beam path to provide optimal tracking performance. The active retinal tracker operates by directing and dithering (at 16 kHz) a beam onto a retinal target (usually the bright lamina cribrosa in the optic nerve head) and sensing with a confocal reflectometer phase shifts when the eye moves the target off the dither circle. The resultant error signals are fed back in high speed closed loop fashion into two transverse galvanometers to maintain lock. In addition to having an integrated design for AO applications, the retinal tracker configuration includes an FPGA-based tracking control board, which performs digital lock-in amplification and other signal processing for robust operation. The tracking system maintains lock with a bandwidth greater than 1 kHz (limited only by the galvanometer inertial constraints) and an accuracy <15 μm.
  • The RT module 206 includes a dual source 225, focusing lens 211, an aperture splitter 236, and a resonant scanner 238.
  • The fluorescence channel 202 channel includes source 218 and a lens 211 for delivering fluorescence excitation beam 241 and lens 211, pinhole 209, filter 239 and PMT 222 for collecting fluorescence emission beam 242.
  • The 1-μm swept source for OCT imaging can have an average output power of 11 mW, a bandwidth (BW) of 79 nm centered at ˜1070 nm, and a duty cycle of 0.65. This bandwidth has a theoretical axial resolution of 4.6 μm in tissue. The wavelength of the OCT illumination beam can be selected to match a physical property of the tissue being imaged. The wavelength can be from 400 nm to about 2.6 microns, although longer or shorter wavelengths can be used depending on the chromophore. Exemplary features to target include the retina or a portion of the retina, blood, retinal pigment epithelial (RPE) cells, a feeder vessel, a drusen, a small tumor, a microaneurysm, or an epiretinal membrane. For example, a wavelength of 680 nm can be used to monitor blood flow in the retina.
  • An OCT illumination wavelength of 1 micron has certain advantages over 850 nm illumination, including in penetration depth into the retina. Choroid and sclera can be imaged. 1 micron scatters less than 850 nm in the eye. Other wavelengths can be used to target or match the optical or light tissue interaction properties of specific layers, cells, organelles or molecules in the retina.
  • All other illumination sources are superluminescent diodes (SLD) that reduce image speckle and tracker noise. The SLO illumination beam centered at ˜750 nm (14 nm BW) also acts as the wavefront sensor beacon. The LSO illumination beam is centered at 830 nm (26 nm BW) and the tracker beam is centered at ˜915 nm. All sources are combined with off-the-shelf dichroic beamsplitters except for D2, which can be custom made to transmit both the 1-μm OCT and 750-nm SLO NIR beams while reflecting the 830-nm LSO and 915-nm RT beams. Despite the number of beams, the instrument is still eye-safe because NIR wavelengths are used: the combined power is low, several times below ANSI thresholds even when all scanners fail.
  • The OCT/SLO scan engine is configured to use a resonant scanner (RS) and single galvanometer for SLO imaging and two galvanometers for OCT imaging. The OCT scan (line, circle, raster, radial, etc.) can be translated and centered anywhere in the wide field of the AO beam path by adjusting offset voltages to the galvanometers. Similarly, the SLO flying spot raster scan can be centered and shifted anywhere in the AO beam path for acquisition of montages and strips. However, because the SLO RS cannot be driven with voltage offsets, the x-axis OCT galvanometer serves the dual function of shifting the SLO raster in this mode.
  • The imaging system shown in FIG. 3 includes various beamsplitters, lens, minors and optics for coupling the various modules so that measurements can be taken. Beamsplitters include pellicle beamsplitter 213 and dichroic beamsplitters 217. One skilled in the art will recognize that other optics can be used to couple the optical modules. Turning minors 212 can be used to fold the optical design. Spherical minors 219 can be used to provide a wide field of view. The imaging system can include a LCD-based fixation target 237. The imaging system can include an optical component (such as a flip mount) 210 for an animal port.
  • FIG. 4 shows a schematic diagram of scanning axes for the SLO and OCT. The SLO flying spot raster is created from the fast axis of scanner 1 and the slow axis of scanner 2. The OCT line or rater is created from the fast axis of scanner 2 and the slow axis of scanner 3. Each scanner can be a galvanometer or other scanning optic known in the art. Scanner 3 can be used to create OCT raters or SLO montages or mosaics (e.g., stitching several high-resolution, low field images together to create a single high-resolution high-field image.
  • FIG. 5 show an example of an instrumentation layout. In FIG. 5, box 300 represents the host computer, box 301 represents the instrumentation rack, and box 302 represents the optical table. The host computer 300 includes framegrabbers 122 for acquiring images and USB ports 307 for the DM controllers. All system instrumentation can be contained in two electronics boxes—a tracker box 308 and an imaging box 309. The tracker box 308 contains the LSO/RT sources, the tracking RS pair, all the system galvanometers, and two custom electronic boards designed to control the retinal tracker in a high bandwidth closed loop manner. The custom track controller board is an FPGA-based real-time processor that controls all hardware, generates all timing and waveform signals and performs the high-speed closed-loop feedback control. The custom tracking motherboard (MB) 310 can be designed so that all off-the-shelf OEM electronic driver boards can be plugged into the system with minimal wiring. The RT control board, OEM resonant scanner and galvanometer boards plug into the MB, which can include an integrated detector and driver/thermo-electric coolers for 2 SLDs.
  • The imaging box 309 contains the real time OCT digitizer and processing board, the SLO source and voltage-controlled RS driver board, and OCT depth stage controller. The RS amplitude (which sets the SLO size) is controlled via the host computer with an analog waveform output from a USB DAQ. The OCT image processing chain can be processed using a graphical processor unit (GPU) on a standard video card.
  • To provide seamless switching between OCT and SLO modes using the same scanning and processing hardware, a switch directs either the RS or swept source sync signals to the high speed digitizer. Both are TTL signals in the kHz range. The digitizer generates a pixel clock (50 MHz), duplicates the line sync, and generates a frame sync signal, which is passed to the framegrabbers via the real time OCT processing board. The real time processing board generates all the waveforms to drive the galvanometers. Thus the HS-WS camera (and hence the correction) is always synchronized to the primary imaging hardware. This prevents a drift in the AO correction across the imaging field. It is not necessary to synchronize the LSO scan. In OCT mode, the signal from the balanced detector generated from the fiber interferometer is input to the high speed digitizer. This signal is not used in SLO mode. Communication between the digitizer, real time OCT processing board, and framegrabbers is accomplished with the CameraLink interface. The hardware used to control the multimodal AO system also includes three framegrabbers (one dual camera), two cameras, two detectors, four sources, five galvanometers, 3 resonant scanners, a motorized stage, and two deformable minors.
  • The custom SLO timing board includes functionality for non-linear pixel clock generation for real-time image de-warping from the sinusoidal resonant scanner drive signal; electronic blanking (clamping) with a high-speed multiplexor for real-time analog signal conditioning; x-y galvanometer waveform generation; resonant scanner amplitude signal generation; dual channel operation for simultaneous reflectance/fluorescence analog signal conditioning; and synchronization with the real-time SDOCT processing board.
  • The multimodal AO retinal imager was tested in six subjects to demonstrate performance capabilities. The subjects were aged between 23 and 53 years and the refractive error was between 0 and 7D (all myopes). A human subject protocol was approved by New England IRB prior to all imaging. All subjects gave informed consent to be imaged. Some of the subjects with small pupils were dilated to enhance AO correction. Subjects that were not dilated often had larger variability in AO and imaging performance, especially when imaging the fovea, which caused the pupil to constrict. All subjects used a bite bar for head stabilization and pupil centration.
  • The imaging sessions did not follow a set protocol but included OCT cross-sectional and raster scans (1-3 mm), SLO images (1- and 2-deg. fields), strip scans, and montages. The montage scans step the SLO offset galvanometers over a matrix with overlap, the size of which (2×2, 3x3, 4×4, etc.) is configured by the user. The SLO strip scanning is an innovation whereby the SLO offset galvanometers are slowly scanned in the horizontal or vertical direction to pan across a retinal patch and produce a stack of images that are significantly overlapping. This aids in automated registration, especially in the presence of excessive eye motion.
  • The system optical performance was characterized first using diffusely reflecting targets at various retinal (i.e., focal) conjugates. Next, the system and AO performance were tested using a model eye consisting of a 25-mm focal length (fl) achromat and a diffusely reflecting “retina.” Finally, the AO correction performance was measured in live human eyes.
  • In initial human subject testing of the dual-DM approach, a control algorithm was used whereby the woofer corrected system, large amplitude and/or low-order sample aberrations and the tweeter corrected small amplitude and/or high-order sample aberrations. To prevent the dual-DM control from causing the correction to oscillate (especially since the response time differed between mirrors), the woofer was initiated first and run in static mode where it could correct the wavefront for a fixed number of cycles and then held while the tweeter was activated after the woofer was frozen and left in dynamic mode. Of course the number of static cycles chosen is critical to insure proper lower-order aberration correction.
  • At the retinal conjugates and in the model eye, both DMs were used although the tweeter corrected only a very small amount of residual aberration.
  • The validation at retinal conjugates and in the model eye was performed by direct measurement of the point spread function (PSF) independent of the HS-WS at a plane conjugate to the SLO detector pinhole using a standard USB CCD camera. The magnification from the SLO confocal pinhole (and CCD position) to the retina is ˜9.25 so a 100-1 μm pinhole projects to roughly 11 μm on the retina, or ˜2.2 times the 4.9-1 μm Airy disc at 750 nm. A 200-1 μm pinhole (−22 μm on the retina) is less confocal allowing more scattered and aberrated light without improving imaging, while a 50-1 μm pinhole (5.4 μm on the retina) is tightly confocal: only 1.1 times the Airy disc. In general, images are first taken with the 100-μm pinhole, and the 50-1 μm pinhole is used for increased contrast in subjects with bright macula and the 200-1 μm pinhole is used for undilated subjects and subjects with dim macula.
  • The PSFs at retinal conjugates two and four (see FIG. 3) for focused illumination are shown in the first three columns in FIG. 6. Note that the system aberration is minimal at r2, with some residual astigmatism. The PSF FWHM (full width half maximum, average of x and y) is 88 μm (9.5 μm at retina). At r4, however, there are significantly more lower order aberrations—the PSF FWHM nearly doubles to ˜152 μm without AO correction. With AO correction, the PSF FWHM is 83 μm, less than two times the Airy disc size.
  • FIG. 6 also shows the PSFs in a model eye with and without AO correction (columns 4-5). With AO correction (both DMs activated), the FWHM decreases to ˜127 from 243 μm. (The CCD may have been slightly saturated, causing a slight overestimation of the PSF width). Some residual astigmatism remains, but AO significantly improves the PSF approximately to the size of the confocal pinhole. In the model eye, AO correction reduced the RMS error from ˜0.6 μm to <0.05 μm and increased the Strehl ratio to 0.92 (as measured by the wave aberration function from the HS-WS).
  • An example of the AO performance achieved in one human subject is shown in FIG. 7. Shown are the wavefront error map (top row) and the PSF (second row) for three cases: no AO correction (first column), DM1 (woofer) correction (second column), and dual-DM (woofer-tweeter) correction (third column). The time course of the correction and the aberrations separated by Zernike order are also shown. The average RMS wavefront error (Strehl ratio) for the three cases was 1.215 (<0.01), 0.097 (0.52), and 0.052 (0.83) μm, respectively. Thus, the dual-DM approach achieved more optimal AO correction in human subjects than could be achieved with a single mirror alone.
  • Examples from 4 of the 6 subjects in each of the three primary imaging modes (LSO, SLO, OCT) are shown in FIG. 8. The LSO image provides a 33 deg. wide field view of the retina. The 2-deg. SLO images were taken near the fovea. Cone photoreceptors can be resolved to within ˜0.5 deg. (100-150 μm) of the fovea. The cross-sectional OCT image spans 2 mm (6.9 deg.) centered on the fovea. The OCT images are composites of between 5 and 10 frames after flattening and alignment. Ten major retinal layers (nerve fiber, ganglion cell, inner plexiform, inner nuclear, outer plexiform, outer nuclear, inner segments, outer segments, retinal pigment epithelium, choriocapillaris) can be resolved.
  • FIG. 9 shows single and 4-frame average cross-sectional FDOCT images through the fovea for one subject that was imaged with both an 850-nm spectrometer-based instrument and the current 1050-nm swept source-based AO-FDOCT imager. Although the axial resolution in the former was better (theoretical axial resolution: 3.6 μm vs. 4.6 μm), the improved penetration into the choroid is clear.
  • An AOSLO montage in the central ˜3 deg. for one subject is shown in FIG. 10. The montage was created by stitching together a 3×3 matrix of 2-deg. AOSLO images. The magnified regions to the right indicate excellent cone contrast within 0.5 deg. (−150 μm) of the fovea center. For imaging larger retinal patches, strip scan and strip montage image scanning procedures can be used to map structures (e.g., photoreceptors) across the macula or retinal region.
  • A montage or mosaic image can be created using a scanning device of the imaging apparatus (e.g., the third scanning device 38 shown in FIG. 1 or a scanner 220 shown in FIG. 3). For example, the scanning device includes a scanner and a driver. The scanner can be a resonant scanner that scans a first portion of the eye (e.g., a first portion of the retina) and the driver can be a galvanometer that repositions the resonant scanner on a second portion of the eye (e.g., a second portion of the retina) according to a predetermined off-set.
  • Thus, a first image (e.g., image) can be acquired by the imaging apparatus when the resonant scanner scans the imaging beam along on the first portion of the eye. The scan can be a raster scan or a two-dimensional transverse scan. A second image (e.g., image) can be acquired by the imaging apparatus after the galvanometer repositions the scanner on the second portion of the eye. The process can be repeated to acquire images over the other portions of the eye until the montage has been generated. An exemplary procedure for recording montage or mosaic images is described in U.S. Pat. No. 7,758,189, the disclosure of which is herein incorporated by reference in its entirety.
  • The automated registration algorithm co-aligns multiple frames for averaging (to increase SNR), for quantification of large retinal patches in the presence of intra-frame warping, to determine the shift in a secondary imaging mode where SNR is extremely low (i.e., fluorescence), or as a precursor to stitching montages or strips together. When aligning a stack of frames from a single fixation point, the algorithm aligns by horizontal strips 10 pixels wide. This makes the registered image more impervious to torsional eye motion that can cause intra-frame warping. As a demonstration of the algorithm capabilities, a stack of AOSLO images taken for the challenging case of high image uniformity (and lack of high contrast vessel targets) in the foveal avascular zone were aligned. FIG. 11 shows the results compared to no registration and registration frame-by-frame.
  • For auto-stitching, our algorithm selects a key frame in a stack, uses the scale invariant feature transform (SIFT) to match frames, and then aligns to the key frames. FIG. 12 shows a registered stack of multimodal AO images from a slow strip scan in the presence of above average eye movements (for a control subject).
  • Cone photoreceptor counts were performed on several retinal patches at various eccentricity from a single 2-deg. AOSLO scan near the fovea (identifiable in the images) for 4 subjects using manual and automated methods (FIG. 13). The automated cone photoreceptor counting algorithm corrects for a non-uniform image background, applies morphological operators, and uses a centroiding algorithm for initial identification of cone locations. The locations are then filtered to provide a final cone count in the retinal patch examined. The final filter parameter is set according to the eccentricity and so requires some limited user input. The manual (solid symbols) and automated (open symbols) results are compared to previously reported histology. In general, the automated result showed good correspondence with the manual counts and histology. For lower eccentricities close to the resolution limit of the instrument, the algorithm begins to break down and underestimate the count.
  • FIG. 14 shows an example of the AO performance achieved in one human subject. Three images are shown: SLO (1 deg. field, top row), WS (second row), and PSF (third row) for three cases: no AO correction (third column), static DM1 (woofer) correction (second column), and dual-DM correction (first column) with both static DM1 (woofer) and dynamic DM2 (tweeter). The time course of the correction and the aberrations broken down by Zernike order are also shown. Both minors are important to achieve the best possible AO correction in human subjects.
  • The multimodal AO system can be configured to acquire images from the SLO and OCT channels sequentially while the LSO, AO, HS-WS, and RT are all running continuously. This can be done in a unique configuration whereby the real time OCT processing board that drives the galvos can accept input from either the SLO RS or the OCT swept source. Thus the multiple scanning schemes available for both modes (OCT line and raster, SLO raster, montages, strip scans, etc.) use all the same hardware (scanners, real time processing board) and are set up from an extremely intuitive and flexible user interface. Another multimodal AO retinal imaging system can include simultaneous SLO and OCT imaging, but it uses a spectrometer-based FDOCT channel. Thus, for some applications that target deeper structures and vasculature, the enhanced depth penetration with 1-1 μm illumination takes precedence over simultaneous OCT/SLO imaging.
  • A suite of post-processing analysis routines for both SLO and OCT images have been developed. The functionality of these algorithms include registration, image averaging, montage and strip stitching, photoreceptor quantification, photoreceptor density mapping, and segmentation (retinal layer and drusen). Some algorithms require limited user input (i.e., are semi-automated) while others operate in a fully automated manner (e.g., photoreceptor counting). With the multimodal image acquisition modes and these analysis tools, it is now possible to fully map retinal layers and critical structures across the entire macula.
  • FIG. 15 shows an exemplary SLO timing board functional schematic. The SLO timing board can include a FPGA-based design to provide further device automation and enhanced performance (e.g., increase SNR from a stable blanking region). The functionality of the timing board can include generation of a non-linear pixel clock for automatic SLO image dewarping, automatic electronic video blanking via high speed analog signal multiplexing, generation of SLO/OCT waveforms and offsets (user-controlled), generation of the SLO resonant scanner amplitude control signal (user-controlled), and/or dual channel video operation that can be coupled to simultaneous reflectance/fluorescence imaging. The SLO timing board includes a TTL reference signal 400, a digital PLL chip 401, a non-linear pixel clock signal 402, a resonant scanner driver 403, a two-channel digital-to-analog converter 404, an RS drive signal 405, an OCT/SLO scanner drive waveforms 406, a four-channel digital-to-analog converter 407, a RS-232 port for host computer communication 408, a field programmable gated array chip 409, framegrabber ports 410, a high speed video multiplexor 412, and a SLO image showing blanking region 413.
  • The above-described techniques can be implemented in digital electronic circuitry, or in computer hardware, firmware, software, or in combinations of them. The implementation can be as a computer program product, i.e., a computer program tangibly embodied in an information carrier, e.g., in a machine-readable storage device or in a propagated signal, for execution by, or to control the operation of, data processing apparatus, e.g., a programmable processor, a computer, or multiple computers. A computer program can be written in any form of programming language, including compiled or interpreted languages, and it can be deployed in any form, including as a stand-alone program or as a module, component, subroutine, or other unit suitable for use in a computing environment. A computer program can be deployed to be executed on one computer or on multiple computers at one site or distributed across multiple sites and interconnected by a communication network.
  • Method steps can be performed by one or more programmable processors executing a computer program to perform functions of the technology by operating on input data and generating output. Method steps can also be performed by, and apparatus can be implemented as, special purpose logic circuitry, e.g., a FPGA (field programmable gate array), a FPAA (field-programmable analog array), a CPLD (complex programmable logic device), a PS oC (Programmable System-on-Chip), ASIP (application-specific instruction-set processor), or an ASIC (application-specific integrated circuit), or the like. Subroutines can refer to portions of the stored computer program and/or the processor, and/or the special circuitry that implement one or more functions.
  • Processors suitable for the execution of a computer program include, by way of example, both general and special purpose microprocessors, and any one or more processors of any kind of digital computer. Generally, a processor will receive instructions and data from a read-only memory or a random access memory or both. The essential elements of a computer are a processor for executing instructions and one or more memory devices for storing instructions and data. Generally, a computer will also include, or be operatively coupled to receive data from or transfer data to, or both, one or more mass storage devices for storing data, e.g., magnetic, magneto-optical disks, or optical disks. Data transmission and instructions can also occur over a communications network. Information carriers suitable for embodying computer program instructions and data include all forms of non-volatile memory, including by way of example semiconductor memory devices, e.g., EPROM, EEPROM, and flash memory devices; magnetic disks, e.g., internal hard disks or removable disks; magneto-optical disks; and CD-ROM and DVD-ROM disks. The processor and the memory can be supplemented by, or incorporated in special purpose logic circuitry.
  • The terms “module” and “function,” as used herein, mean, but are not limited to, a software or hardware component which performs certain tasks. A module may advantageously be configured to reside on addressable storage medium and configured to execute on one or more processors. A module may be fully or partially implemented with a general purpose integrated circuit (IC), DSP, FPGA or ASIC. Thus, a module may include, by way of example, components, such as software components, object-oriented software components, class components and task components, processes, functions, attributes, procedures, subroutines, segments of program code, drivers, firmware, microcode, circuitry, data, databases, data structures, tables, arrays, and variables. The functionality provided for in the components and modules may be combined into fewer components and modules or further separated into additional components and modules. Additionally, the components and modules may advantageously be implemented on many different platforms, including computers, computer servers, data communications infrastructure equipment such as application-enabled switches or routers, or telecommunications infrastructure equipment, such as public or private telephone switches or private branch exchanges (PBX). In any of these cases, implementation may be achieved either by writing applications that are native to the chosen platform, or by interfacing the platform to one or more external application engines.
  • To provide for interaction with a user, the above described techniques can be implemented on a computer having a display device, e.g., a CRT (cathode ray tube) or LCD (liquid crystal display) monitor, for displaying information to the user and a keyboard and a pointing device, e.g., a mouse or a trackball, by which the user can provide input to the computer (e.g., interact with a user interface element). Other kinds of devices can be used to provide for interaction with a user as well; for example, feedback provided to the user can be any form of sensory feedback, e.g., visual feedback, auditory feedback, or tactile feedback; and input from the user can be received in any form, including acoustic, speech, or tactile input.
  • The above described techniques can be implemented in a distributed computing system that includes a back-end component, e.g., as a data server, and/or a middleware component, e.g., an application server, and/or a front-end component, e.g., a client computer having a graphical user interface and/or a Web browser through which a user can interact with an example implementation, or any combination of such back-end, middleware, or front-end components. The components of the system can be interconnected by any form or medium of digital data communication, e.g., a communication network. Examples of communication networks include a local area network (“LAN”) and a wide area network (“WAN”), e.g., the Internet, and include both wired and wireless networks. Communication networks can also all or a portion of the PSTN, for example, a portion owned by a specific carrier.
  • The computing system can include clients and servers. A client and server are generally remote from each other and typically interact through a communication network. The relationship of client and server arises by virtue of computer programs running on the respective computers and having a client-server relationship to each other.
  • While the invention has been particularly shown and described with reference to specific illustrative embodiments, it should be understood that various changes in form and detail may be made without departing from the spirit and scope of the invention.

Claims (27)

What is claimed is:
1. An optical apparatus comprising:
a system of optical components capable of operating in a scanning laser ophthalmoscope (SLO) mode and an optical coherence tomography (OCT) mode,
the system of optical components including:
a first optical module for the SLO mode including:
a first source adapted to provide a first imaging beam for the SLO mode;
a first detection device configured to receive a first signal associated with
a first image of a retina of an eye;
a second optical module for the OCT mode including:
a second source adapted to provide a second imaging beam for the OCT mode;
a second detection device configured to receive a second signal associated with a second image of the retina; and
a first scanning device configured (i) to move the first imaging beam along the retina in the slow axis of the SLO mode to acquire the first image and (ii) to move the second imaging beam along the retina in the fast axis of the OCT mode to acquire the second image.
2. The apparatus of claim 1 further comprising:
a second scanning device configured to move the first imaging beam along the retina in the fast axis of the SLO mode to acquire the first image; and
a third scanning device configured to move the second imaging beam along the retina in the slow axis of the OCT mode to acquire the second image.
3. The apparatus of claim 2 wherein the first scanning device, the second scanning device and the third scanning device are positioned at pupil conjugates in the system of optical components.
4. The apparatus of claim 2 wherein the first scanning device is mounted to the third scanning device at a pupil conjugate.
5. The apparatus of claim 1 wherein the second imaging beam of the OCT mode is introduced by a beamsplitter positioned between the eye and the SLO module.
6. The apparatus of claim 1 wherein system of optical components are adapted to simultaneously image the same retinal coordinates in the SLO mode and OCT mode.
7. The apparatus of claim 2 wherein the third scanning device is configured to scan the first imaging beam to generate a mosaic image of the eye.
8. The apparatus of claim 1 further comprising a third optical module configured to (i) detect an optical distortion and (ii) correct the optical distortion in at least one of the first or second imaging beams scanned on the eye.
9. The apparatus of claim 8 wherein the third optical module comprises:
a wavefront sensor adapted to detect the optical distortion; and
a wavefront compensator adapted to correct the optical distortion in the first or second imaging beam.
10. The apparatus of claim 5 further comprising a first wavefront compensator and a second wavefront compensator positioned between the beamsplitter and the eye.
11. The apparatus of claim 1 further comprising a fourth optical module configured to operate in a line scanning ophthalmoscope (LSO) mode, the fourth optical module including:
a third source adapted to provide a third imaging beam in a line focus configuration for the LSO mode, wherein the fourth optical module is configured to (i) scan the third imaging beam in the line focus configuration along the retina in a second dimension and (ii) descan the second light returning from the eye in the second dimension, the light returning from the eye directed to a third detection device.
12. The apparatus of claim 1 further comprising a fifth optical module adapted to track a reference feature of the retina of the eye, the first optical module adapted to control the position of the first imaging beam relative to the reference feature to correct for motion of the eye.
13. The apparatus of claim 1 further comprising a sixth optical module adapted to provide a fluorescence imaging channel.
14. The apparatus of claim 1 wherein the OCT mode can include a Fourier domain OCT channel configured to be spectrometer-based or swept source-based.
15. The apparatus of claim 1 wherein the system of optical components further comprises at least two spherical minors, each having a diameter greater than 20 cm, positioned relative to the eye and configured to provide a field of view greater than 30 degrees.
16. The apparatus of claim 1 wherein the wavelength of the second imaging beam of the OCT mode is selected to match a physical property of the tissue.
17. A method of imaging a retina of an eye, comprising:
acquiring a SLO image of the eye by receiving, on a first detector, a first light returning from the eye and providing a first electrical signal responsive to the first light at each of a plurality of locations along the first detector, the first electrical signal indicative of the SLO image of the eye; and
acquiring an OCT image of the eye by receiving, on a second detector, a second light returning from the eye and providing a second electrical signal responsive to the second light at each of a plurality of locations along the second detector, the second electrical signal combined with a reference signal from a reference arm, the second electrical signal and the reference signal associated with the OCT image of the eye; and
scanning, using a first scanning device, (i) a first imaging beam along the retina in the slow axis of the SLO mode to acquire the SLO image and (ii) a second imaging beam along the retina in the fast axis of the OCT mode to acquire the OCT image.
18. The method of claim 17 further comprising:
scanning, using a second scanning device, the first imaging beam along the retina in the fast axis of the SLO mode to acquire the SLO image; and
scanning, using a third scanning device, the second imaging beam along the retina in the slow axis of the OCT mode to acquire the OCT image.
19. The method of claim 17 further comprising introducing, using a beamsplitter, the second imaging beam of the OCT mode between the eye and the SLO mode.
20. The method of claim 17 further comprising simultaneously imaging the same retinal coordinates in the SLO mode and OCT mode.
21. The method of claim 17 further comprising.
detecting an optical distortion; and
correcting the optical distortion in at least one of the first or second imaging beams scanned on the eye.
22. The method of claim 17 further comprising acquiring a LSO image of the eye by receiving, on a one-dimensional detector, a third light returning from the eye and providing a third electrical signal responsive to the third light at each of a plurality of locations along the one-dimensional detector, the second electrical signal indicative of the LSO image of the eye.
23. The method of claim 17 further comprising:
tracking a reference feature of the retina of the eye; and
controlling the position of the first imaging beam relative to the reference feature to correct for motion of the eye.
24. The method of claim 17 further comprising providing simultaneous, high-fidelity, wide dynamic range correction of lower- and higher-order ocular aberrations using a dual-deformable mirror configuration.
25. The method of claim 17 further comprising imaging a field of view greater than 30 degrees using at least two spherical minors, each having a diameter greater than 20 cm, positioned relative to the eye.
26. An optical apparatus comprising:
a system of optical components capable of operating in a scanning laser ophthalmoscope (SLO) mode and an optical coherence tomography (OCT) mode,
the system of optical components including:
at least two spherical minors, each having a diameter greater than 20 cm, positioned relative to the eye;
at least two deformable mirrors positioned behind the at least two spherical minors;
a beamsplitter positioned behind the at least two deformable mirrors;
an OCT optical module introduced by the beamsplitter;
a SLO optical module behind the beamsplitter;
a first scanning device positioned between the beamsplitter and the eye, the first scanning device configured (i) to move a first imaging beam along the retina in the slow axis of the SLO mode to acquire an SLO image and (ii) to move a second imaging beam along the retina in the fast axis of the OCT mode to acquire an OCT image;
a second scanning device positioned behind the beamsplitter, the second scanning device configured to move the first imaging beam along the retina in the fast axis of the SLO mode to acquire the SLO image; and
a third scanning device positioned between the beamsplitter and the eye, the third scanning device configured to move the second imaging beam along the retina in the slow axis of the OCT mode to acquire the OCT image.
27. The apparatus of claim 26 wherein the at least two deformable mirrors, the first scanning device, the second scanning device and the third scanning device are positioned at pupil conjugates in the system of optical components.
US14/192,183 2010-01-21 2014-02-27 Multi-Functional Adaptive Optics Retinal Imaging Abandoned US20140247425A1 (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
US14/192,183 US20140247425A1 (en) 2010-01-21 2014-02-27 Multi-Functional Adaptive Optics Retinal Imaging

Applications Claiming Priority (3)

Application Number Priority Date Filing Date Title
US29712810P 2010-01-21 2010-01-21
US13/011,404 US8696122B2 (en) 2010-01-21 2011-01-21 Multi-functional adaptive optics retinal imaging
US14/192,183 US20140247425A1 (en) 2010-01-21 2014-02-27 Multi-Functional Adaptive Optics Retinal Imaging

Related Parent Applications (1)

Application Number Title Priority Date Filing Date
US13/011,404 Continuation US8696122B2 (en) 2010-01-21 2011-01-21 Multi-functional adaptive optics retinal imaging

Publications (1)

Publication Number Publication Date
US20140247425A1 true US20140247425A1 (en) 2014-09-04

Family

ID=43877183

Family Applications (2)

Application Number Title Priority Date Filing Date
US13/011,404 Active 2031-10-29 US8696122B2 (en) 2010-01-21 2011-01-21 Multi-functional adaptive optics retinal imaging
US14/192,183 Abandoned US20140247425A1 (en) 2010-01-21 2014-02-27 Multi-Functional Adaptive Optics Retinal Imaging

Family Applications Before (1)

Application Number Title Priority Date Filing Date
US13/011,404 Active 2031-10-29 US8696122B2 (en) 2010-01-21 2011-01-21 Multi-functional adaptive optics retinal imaging

Country Status (5)

Country Link
US (2) US8696122B2 (en)
EP (1) EP2525706A2 (en)
JP (2) JP5596797B2 (en)
CA (1) CA2787336A1 (en)
WO (1) WO2011091253A2 (en)

Cited By (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN105105707A (en) * 2015-09-15 2015-12-02 中国科学院光电技术研究所 Common-path interference adaptive optical OCT retina imager
US10052018B2 (en) 2016-04-06 2018-08-21 Canon Kabushiki Kaisha Wavefront measuring method for adaptive optics system
US10238279B2 (en) 2015-02-06 2019-03-26 Duke University Stereoscopic display systems and methods for displaying surgical data and information in a surgical microscope
WO2019056042A1 (en) * 2017-09-19 2019-03-28 Ellex Medical Pty Ltd Dual camera ophthalmic imaging
US10660519B2 (en) 2014-01-30 2020-05-26 Duke University Systems and methods for eye tracking for motion corrected ophthalmic optical coherence tomography
US10694939B2 (en) 2016-04-29 2020-06-30 Duke University Whole eye optical coherence tomography(OCT) imaging systems and related methods
US10835119B2 (en) 2015-02-05 2020-11-17 Duke University Compact telescope configurations for light scanning systems and methods of using the same

Families Citing this family (64)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
GB0913911D0 (en) 2009-08-10 2009-09-16 Optos Plc Improvements in or relating to laser scanning systems
JP5845608B2 (en) * 2011-03-31 2016-01-20 株式会社ニデック Ophthalmic imaging equipment
CN103502770B (en) * 2011-04-29 2017-02-08 光视有限公司 Improved imaging with real-time tracking using optical coherence tomography
JP5847510B2 (en) * 2011-09-20 2016-01-20 キヤノン株式会社 Image processing apparatus and image processing method
US8581643B1 (en) * 2011-10-28 2013-11-12 Lightlab Imaging, Inc. Phase-lock loop-based clocking system, methods and apparatus
US9060718B2 (en) * 2012-02-13 2015-06-23 Massachusetts Institute Of Technology Methods and apparatus for retinal imaging
JP6114495B2 (en) * 2012-02-20 2017-04-12 キヤノン株式会社 Image display device, image display method, and imaging system
JP6025349B2 (en) * 2012-03-08 2016-11-16 キヤノン株式会社 Image processing apparatus, optical coherence tomography apparatus, image processing method, and optical coherence tomography method
US9357916B2 (en) * 2012-05-10 2016-06-07 Carl Zeiss Meditec, Inc. Analysis and visualization of OCT angiography data
CN102860815B (en) * 2012-09-11 2014-10-08 中国科学院光电技术研究所 Self-adaptive confocal scanning retina imaging method and device based on line scanning confocal imaging image guidance
CN102908119A (en) * 2012-09-26 2013-02-06 温州医学院眼视光研究院 Confocal scanning and imaging system and astigmation control method
GB201217538D0 (en) * 2012-10-01 2012-11-14 Optos Plc Improvements in or relating to scanning laser ophthalmoscopes
CA2887052C (en) 2012-10-12 2020-07-07 Thorlabs, Inc. Compact, low dispersion, and low aberration adaptive optics scanning system
JP6008702B2 (en) * 2012-11-09 2016-10-19 キヤノン株式会社 Compensating optical device, compensating optical device control method, and ophthalmic device
CN102973241B (en) * 2012-12-08 2015-04-22 中国科学院光电技术研究所 Laser diffraction line scanning confocal ophthalmoscope system based on adaptive optics
US8783868B2 (en) * 2012-12-21 2014-07-22 Carl Zeiss Meditec, Inc. Two-dimensional confocal imaging using OCT light source and scan optics
EP3000382A1 (en) * 2012-12-28 2016-03-30 Canon Kabushiki Kaisha Image processing apparatus and image processing method
JP6230262B2 (en) * 2012-12-28 2017-11-15 キヤノン株式会社 Image processing apparatus and image processing method
CN103054550B (en) * 2013-01-17 2015-05-06 中国科学院光电技术研究所 Line scanning confocal ophthalmoscope system based on adaptive optics
JP6193576B2 (en) * 2013-01-31 2017-09-06 キヤノン株式会社 Ophthalmic apparatus and control method
US9778492B2 (en) * 2013-02-28 2017-10-03 Johnson & Johnson Vision Care, Inc. Electronic ophthalmic lens with lid position sensor
US20140268040A1 (en) * 2013-03-14 2014-09-18 Physical Sciences, Inc. Multimodal Ocular Imager
US20150002812A1 (en) * 2013-06-27 2015-01-01 Nidek Co., Ltd. Image processing apparatus and storage medium
EP3021735A4 (en) 2013-07-19 2017-04-19 The General Hospital Corporation Determining eye motion by imaging retina. with feedback
US9406133B2 (en) * 2014-01-21 2016-08-02 University Of Rochester System and method for real-time image registration
US9237847B2 (en) 2014-02-11 2016-01-19 Welch Allyn, Inc. Ophthalmoscope device
US9211064B2 (en) 2014-02-11 2015-12-15 Welch Allyn, Inc. Fundus imaging system
US10143370B2 (en) * 2014-06-19 2018-12-04 Novartis Ag Ophthalmic imaging system with automatic retinal feature detection
US9814386B2 (en) 2014-07-02 2017-11-14 IDx, LLC Systems and methods for alignment of the eye for ocular imaging
JP2016042931A (en) * 2014-08-20 2016-04-04 株式会社トプコン Ophthalmologic apparatus
JP6543483B2 (en) * 2015-02-27 2019-07-10 株式会社トプコン Ophthalmic device
US10799115B2 (en) 2015-02-27 2020-10-13 Welch Allyn, Inc. Through focus retinal image capturing
US11045088B2 (en) 2015-02-27 2021-06-29 Welch Allyn, Inc. Through focus retinal image capturing
US20180028059A1 (en) * 2015-03-24 2018-02-01 Forus Health Private Limited An apparatus for multi-mode imaging of eye
CN104783755A (en) 2015-04-29 2015-07-22 中国科学院光电技术研究所 Adaptive optical retinal imaging apparatus and method
US9775515B2 (en) * 2015-05-28 2017-10-03 University Of Rochester System and method for multi-scale closed-loop eye tracking with real-time image montaging
US10136804B2 (en) 2015-07-24 2018-11-27 Welch Allyn, Inc. Automatic fundus image capture system
WO2017035296A1 (en) * 2015-08-25 2017-03-02 Indiana University Research And Technology Corporation Systems and methods for specifying the quality of the retinal image over the entire visual field
US10772495B2 (en) 2015-11-02 2020-09-15 Welch Allyn, Inc. Retinal image capturing
US10413179B2 (en) 2016-01-07 2019-09-17 Welch Allyn, Inc. Infrared fundus imaging system
JP6866132B2 (en) * 2016-02-17 2021-04-28 キヤノン株式会社 Ophthalmic devices, control methods and programs for ophthalmic devices
JP6736304B2 (en) * 2016-02-18 2020-08-05 株式会社トプコン Ophthalmic imaging device
EP3213668B1 (en) * 2016-03-03 2021-07-28 Nidek Co., Ltd. Ophthalmic image processing apparatus
US9867538B2 (en) 2016-03-21 2018-01-16 Canon Kabushiki Kaisha Method for robust eye tracking and ophthalmologic apparatus therefor
US10010247B2 (en) 2016-04-26 2018-07-03 Optos Plc Retinal image processing
US9978140B2 (en) 2016-04-26 2018-05-22 Optos Plc Retinal image processing
CN107126189B (en) 2016-05-31 2019-11-22 瑞尔明康(杭州)医疗科技有限公司 Optical module and retina image-forming equipment for retina image-forming
US10602926B2 (en) 2016-09-29 2020-03-31 Welch Allyn, Inc. Through focus retinal image capturing
US10595770B2 (en) * 2016-10-19 2020-03-24 The Regents Of The University Of California Imaging platform based on nonlinear optical microscopy for rapid scanning large areas of tissue
FR3065365B1 (en) * 2017-04-25 2022-01-28 Imagine Eyes MULTI-SCALE RETINAL IMAGING SYSTEM AND METHOD
CN109426053A (en) 2017-08-31 2019-03-05 中强光电股份有限公司 Projector and light source module
US10448828B2 (en) 2017-12-28 2019-10-22 Broadspot Imaging Corp Multiple off-axis channel optical imaging device with rotational montage
US10610094B2 (en) 2017-12-28 2020-04-07 Broadspot Imaging Corp Multiple off-axis channel optical imaging device with secondary fixation target for small pupils
US10966603B2 (en) 2017-12-28 2021-04-06 Broadspot Imaging Corp Multiple off-axis channel optical imaging device with overlap to remove an artifact from a primary fixation target
US11096574B2 (en) 2018-05-24 2021-08-24 Welch Allyn, Inc. Retinal image capturing
JP2018196823A (en) * 2018-09-25 2018-12-13 株式会社トプコン Ophthalmologic apparatus
JP2022512391A (en) * 2018-12-12 2022-02-03 エコール・ポリテクニーク・フェデラル・ドゥ・ローザンヌ (ウ・ペ・エフ・エル) Ophthalmic systems and methods for clinical devices with transscleral illumination with multiple point sources
CN110236485B (en) * 2019-07-16 2022-02-18 天津市索维电子技术有限公司 Device and method for measuring retina topography
US11525782B2 (en) * 2019-09-03 2022-12-13 Tianma Japan, Ltd. Fluorescent image analyzer
CN110584592B (en) * 2019-09-09 2021-06-18 中国科学院苏州生物医学工程技术研究所 Large-field-of-view adaptive optical retina imaging system and method for common-path beam scanning
GB201914750D0 (en) * 2019-10-11 2019-11-27 Ttp Plc Multifunctional ophthalmic device
CA3096285A1 (en) * 2020-10-16 2022-04-16 Pulsemedica Corp. Opthalmological imaging and laser delivery device, system and methods
CN112286107A (en) * 2020-11-03 2021-01-29 上海奕太智能科技有限公司 FPGA-based adaptive optical closed-loop control system and control method
CA3100460A1 (en) 2020-11-24 2022-05-24 Pulsemedica Corp. Spatial light modulation targeting of therapeutic lasers for treatment of ophthalmological conditions

Citations (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20110001927A1 (en) * 2008-02-01 2011-01-06 Linos Photonics Gmbh & Co., Kg Fundus scanning apparatus

Family Cites Families (79)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US4264152A (en) 1979-02-26 1981-04-28 Sri International Visual stimulus deflector
US4443075A (en) 1981-06-26 1984-04-17 Sri International Stabilized visual system
US4569354A (en) 1982-03-22 1986-02-11 Boston University Method and apparatus for measuring natural retinal fluorescence
DE3245939C2 (en) 1982-12-11 1985-12-19 Fa. Carl Zeiss, 7920 Heidenheim Device for generating an image of the fundus
US4561436A (en) 1983-10-28 1985-12-31 Cooper Lasersonics, Inc. Optical system for surgical ophthalmic laser instrument
FR2555039B1 (en) 1983-11-21 1986-04-04 Centre Nat Rech Scient SCANNING CATADIOPTRIC OPHTHALMOSCOPE
US4964717A (en) 1984-03-16 1990-10-23 The Trustees Of Columbia University In The City Of New York Ophthalmic image stabilization system
US4768873A (en) 1985-09-17 1988-09-06 Eye Research Institute Of Retina Foundation Double scanning optical apparatus and method
US4765730A (en) 1985-09-17 1988-08-23 Eye Research Institute Of Retina Foundation Double scanning optical apparatus and method
US4764005A (en) 1985-09-17 1988-08-16 Eye Research Institute Of Retina Foundation Double scanning optical apparatus
JPS6294153A (en) 1985-10-18 1987-04-30 興和株式会社 Laser beam coagulation apparatus
JPS62266032A (en) 1986-05-12 1987-11-18 興和株式会社 Eyeground examination apparatus
US4856891A (en) 1987-02-17 1989-08-15 Eye Research Institute Of Retina Foundation Eye fundus tracker/stabilizer
US4768874A (en) 1987-09-10 1988-09-06 Eye Research Institute Of Retina Foundation Scanning optical apparatus and method
US4931053A (en) 1988-01-27 1990-06-05 L'esperance Medical Technologies, Inc. Method and apparatus for enhanced vascular or other growth
US4881808A (en) 1988-02-10 1989-11-21 Intelligent Surgical Lasers Imaging system for surgical lasers
US4924507A (en) 1988-02-11 1990-05-08 The United States Of America As Represented By The Administrator Of The National Aeronautics And Space Administration Real-time optical multiple object recognition and tracking system and method
US4883061A (en) 1988-02-29 1989-11-28 The Board Of Trustees Of The University Of Illinois Method and apparatus for measuring the thickness of eye components
CH676419A5 (en) 1988-10-06 1991-01-31 Lasag Ag
US5098426A (en) 1989-02-06 1992-03-24 Phoenix Laser Systems, Inc. Method and apparatus for precision laser surgery
DE69017249T2 (en) 1989-04-10 1995-08-03 Kowa Co Ophthalmic measuring method and device.
JPH03128033A (en) 1989-10-16 1991-05-31 Kowa Co Ophthalmological machinery
US5016643A (en) 1990-05-02 1991-05-21 Board Of Regents, The University Of Texas System Vascular entoptoscope
US5094523A (en) 1990-05-11 1992-03-10 Eye Research Institute Of Retina Foundation Bidirectional light steering apparatus
US5029220A (en) 1990-07-31 1991-07-02 The United States Of America As Represented By The Administrator Of The National Aeronautics And Space Administration Optical joint correlator for real-time image tracking and retinal surgery
US5106184A (en) 1990-08-13 1992-04-21 Eye Research Institute Of Retina Foundation Retinal laser doppler apparatus having eye tracking system
JP3165144B2 (en) 1990-10-26 2001-05-14 株式会社ニデック Binocular indirect mirror laser treatment system
JP3165186B2 (en) 1991-07-31 2001-05-14 株式会社ニデック Light therapy equipment
JP3186799B2 (en) 1991-09-17 2001-07-11 興和株式会社 3D shape measuring device
RU94030810A (en) 1991-11-06 1996-06-20 Т.Лай Шуй Pulse laser apparatus, method of providing smooth ablation of matter, laser apparatus and cornea surgery method
US5309187A (en) 1992-03-18 1994-05-03 Ocular Instruments, Inc. High magnification ophthalmic lens
US5437274A (en) 1993-02-25 1995-08-01 Gholam A. Peyman Method of visualizing submicron-size vesicles and particles in blood circulation
JP3369623B2 (en) 1993-03-16 2003-01-20 興和株式会社 Laser scanning ophthalmic imaging device
US5360424A (en) 1993-06-04 1994-11-01 Summit Technology, Inc. Tracking system for laser surgery
US5778016A (en) 1994-04-01 1998-07-07 Imra America, Inc. Scanning temporal ultrafast delay methods and apparatuses therefor
US5980513A (en) 1994-04-25 1999-11-09 Autonomous Technologies Corp. Laser beam delivery and eye tracking system
US5526189A (en) 1994-10-26 1996-06-11 Heacock; Gregory L. Lens for observation of the interior of the eye
US5480396A (en) 1994-12-09 1996-01-02 Simon; Gabriel Laser beam ophthalmological surgery method and apparatus
CA2168404C (en) 1995-02-01 2007-07-10 Dale Schulze Surgical instrument with expandable cutting element
US5782822A (en) 1995-10-27 1998-07-21 Ir Vision, Inc. Method and apparatus for removing corneal tissue with infrared laser radiation
US5726443A (en) 1996-01-18 1998-03-10 Chapman Glenn H Vision system and proximity detector
IL117241A (en) 1996-02-23 2000-09-28 Talia Technology Ltd Three dimensional imaging apparatus and a method for use thereof
US5784148A (en) 1996-04-09 1998-07-21 Heacock; Gregory Lee Wide field of view scanning laser ophthalmoscope
US5673097A (en) 1996-04-15 1997-09-30 Odyssey Optical Systems Llc Portable scanning laser ophthalmoscope
US5767941A (en) 1996-04-23 1998-06-16 Physical Sciences, Inc. Servo tracking system utilizing phase-sensitive detection of reflectance variations
GB9618691D0 (en) 1996-09-06 1996-10-16 Univ Aberdeen Scanning laser ophthalmoscope
US5777719A (en) 1996-12-23 1998-07-07 University Of Rochester Method and apparatus for improving vision and the resolution of retinal images
JP3411780B2 (en) 1997-04-07 2003-06-03 レーザーテック株式会社 Laser microscope and pattern inspection apparatus using this laser microscope
US6027216A (en) 1997-10-21 2000-02-22 The Johns University School Of Medicine Eye fixation monitor and tracker
US5976502A (en) 1997-10-21 1999-11-02 Gholam A. Peyman Method of visualizing particles and blood cells containing a fluorescent lipophilic dye in the retina and choroid of the eye
AUPP062197A0 (en) 1997-11-28 1998-01-08 Lions Eye Institute Of Western Australia Incorporated, The Stereo scanning laser ophthalmoscope
JP3964035B2 (en) * 1998-03-12 2007-08-22 興和株式会社 Ophthalmic equipment
JP2000060893A (en) 1998-08-20 2000-02-29 Kowa Co Ophthalmological treatment device
US6275718B1 (en) 1999-03-23 2001-08-14 Philip Lempert Method and apparatus for imaging and analysis of ocular tissue
US6305804B1 (en) 1999-03-25 2001-10-23 Fovioptics, Inc. Non-invasive measurement of blood component using retinal imaging
US6186628B1 (en) 1999-05-23 2001-02-13 Jozek F. Van de Velde Scanning laser ophthalmoscope for selective therapeutic laser
US6199986B1 (en) 1999-10-21 2001-03-13 University Of Rochester Rapid, automatic measurement of the eye's wave aberration
US6331059B1 (en) 2001-01-22 2001-12-18 Kestrel Corporation High resolution, multispectral, wide field of view retinal imager
US6595643B2 (en) 2001-06-05 2003-07-22 Adaptive Optics Associates,.Inc. Ophthalmic imaging instrument that measures and compensates for phase aberrations in reflections derived from light produced by an imaging light source
JP4157839B2 (en) * 2001-08-30 2008-10-01 ユニバーシティー オブ ロチェスター Retinal region imaging method and system for living eye
US7113817B1 (en) 2001-10-04 2006-09-26 Wintec, Llc Optical imaging of blood circulation velocities
WO2003105678A2 (en) 2002-06-12 2003-12-24 Advanced Research And Technology Institute, Inc. Method and apparatus for improving both lateral and axial resolution in ophthalmoscopy
US6758564B2 (en) 2002-06-14 2004-07-06 Physical Sciences, Inc. Line-scan laser ophthalmoscope
US7404640B2 (en) 2002-06-14 2008-07-29 Physical Sciences, Inc. Monitoring blood flow in the retina using a line-scanning laser ophthalmoscope
US7284862B1 (en) 2003-11-13 2007-10-23 Md Lasers & Instruments, Inc. Ophthalmic adaptive-optics device with a fast eye tracker and a slow deformable mirror
DE10360570B4 (en) * 2003-12-22 2006-01-12 Carl Zeiss Optical measuring system and optical measuring method
US20050146784A1 (en) 2004-01-06 2005-07-07 Vogt William I. Confocal microscope having multiple independent excitation paths
WO2005122872A2 (en) 2004-06-10 2005-12-29 Optimedica Corporation Scanning ophthalmic fixation method and apparatus
JP4916779B2 (en) * 2005-09-29 2012-04-18 株式会社トプコン Fundus observation device
JP4819478B2 (en) * 2005-10-31 2011-11-24 株式会社ニデック Ophthalmic imaging equipment
US7758189B2 (en) 2006-04-24 2010-07-20 Physical Sciences, Inc. Stabilized retinal imaging with adaptive optics
WO2007130411A2 (en) 2006-05-01 2007-11-15 Physical Sciences, Inc. Hybrid spectral domain optical coherence tomography line scanning laser ophthalmoscope
JP4822969B2 (en) * 2006-07-27 2011-11-24 株式会社ニデック Ophthalmic imaging equipment
EP2066225B1 (en) * 2006-09-26 2014-08-27 Oregon Health and Science University In vivo structural and flow imaging
GB0619616D0 (en) 2006-10-05 2006-11-15 Oti Ophthalmic Technologies Optical imaging apparatus with spectral detector
JP5057810B2 (en) * 2007-03-16 2012-10-24 株式会社ニデック Scanning laser optometry equipment
US7690791B2 (en) * 2007-11-05 2010-04-06 Oti Ophthalmic Technologies Inc. Method for performing micro-perimetry and visual acuity testing
JP5209377B2 (en) 2008-06-02 2013-06-12 株式会社ニデック Fundus photographing device
EP2378951A1 (en) 2009-01-15 2011-10-26 Physical Sciences, Inc. Adaptive optics line scanning ophthalmoscope

Patent Citations (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20110001927A1 (en) * 2008-02-01 2011-01-06 Linos Photonics Gmbh & Co., Kg Fundus scanning apparatus

Cited By (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US10660519B2 (en) 2014-01-30 2020-05-26 Duke University Systems and methods for eye tracking for motion corrected ophthalmic optical coherence tomography
US10835119B2 (en) 2015-02-05 2020-11-17 Duke University Compact telescope configurations for light scanning systems and methods of using the same
US10238279B2 (en) 2015-02-06 2019-03-26 Duke University Stereoscopic display systems and methods for displaying surgical data and information in a surgical microscope
CN105105707A (en) * 2015-09-15 2015-12-02 中国科学院光电技术研究所 Common-path interference adaptive optical OCT retina imager
US10052018B2 (en) 2016-04-06 2018-08-21 Canon Kabushiki Kaisha Wavefront measuring method for adaptive optics system
US10694939B2 (en) 2016-04-29 2020-06-30 Duke University Whole eye optical coherence tomography(OCT) imaging systems and related methods
WO2019056042A1 (en) * 2017-09-19 2019-03-28 Ellex Medical Pty Ltd Dual camera ophthalmic imaging

Also Published As

Publication number Publication date
JP2013517842A (en) 2013-05-20
JP5771259B2 (en) 2015-08-26
WO2011091253A2 (en) 2011-07-28
WO2011091253A3 (en) 2011-11-03
CA2787336A1 (en) 2011-07-28
EP2525706A2 (en) 2012-11-28
JP2014028319A (en) 2014-02-13
US8696122B2 (en) 2014-04-15
US20110234978A1 (en) 2011-09-29
JP5596797B2 (en) 2014-09-24

Similar Documents

Publication Publication Date Title
US8696122B2 (en) Multi-functional adaptive optics retinal imaging
Liu et al. Trans-retinal cellular imaging with multimodal adaptive optics
US7466423B2 (en) Optical mapping apparatus
Mujat et al. High resolution multimodal clinical ophthalmic imaging system
Burns et al. Large-field-of-view, modular, stabilized, adaptive-optics-based scanning laser ophthalmoscope
US7118216B2 (en) Method and apparatus for using adaptive optics in a scanning laser ophthalmoscope
US8444268B2 (en) Stabilized retinal imaging with adaptive optics
JP5455001B2 (en) Optical tomographic imaging apparatus and control method for optical tomographic imaging apparatus
JP5822485B2 (en) Image processing apparatus, image processing method, image processing system, SLO apparatus, and program
US9089289B2 (en) Optical imaging system
CA2749622A1 (en) Adaptive optics line scanning ophthalmoscope
JP2014045907A (en) Ophthalmologic apparatus, control method for the same, and program
AU766296B2 (en) High resolution device for observing a body
Wells-Gray et al. Volumetric imaging of rod and cone photoreceptor structure with a combined adaptive optics-optical coherence tomography-scanning laser ophthalmoscope
JP2013063216A (en) Image processing apparatus and image processing method
US20130229620A1 (en) Enhanced Sensitivity Line Field Detection
US11241153B2 (en) Method and apparatus for parallel optical coherence tomographic funduscope
Hammer et al. Multimodal adaptive optics for depth-enhanced high-resolution ophthalmic imaging
JP2020151094A (en) Ophthalmologic apparatus
Hammer et al. Advanced capabilities of the multimodal adaptive optics imager
JP6839310B2 (en) Optical tomography imaging device, its control method, and program
WO2019198629A1 (en) Image processing device and control method for same
JP2015039581A (en) Optical tomographic imaging device
JP2020151096A (en) Ophthalmologic apparatus

Legal Events

Date Code Title Description
AS Assignment

Owner name: PHYSICAL SCIENCES, INC., MASSACHUSETTS

Free format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNORS:HAMMER, DANIEL X.;FERGUSON, R. DANIEL;MUJAT, MIRCEA;AND OTHERS;SIGNING DATES FROM 20140314 TO 20140813;REEL/FRAME:033880/0437

STCB Information on status: application discontinuation

Free format text: ABANDONED -- FAILURE TO RESPOND TO AN OFFICE ACTION