Patent Grant
10078226
The application is generally related to the field of diagnostic medicine. More specifically, the application is directed to a hand-held or bench top ophthalmic device having an optical assembly that provides an enhanced field of view of the eye of a patient and enables enhanced diagnostic eye examinations, such as diabetic retinopathy, to be reliably performed. Real time images that are captured by the ophthalmic device can be directed to a portable electronic device, such as a smartphone, which can be integrated with the instrument to receive images or be remotely connected therewith.
Ophthalmoscopes are commonly known medical diagnostic instruments used to perform routine examinations of the eye of a patient during a primary physician's visit. Due to their relatively low cost, these instruments are commonly found in the physician's office, hospitals and urgent care medical facilities. A typical ophthalmoscope is defined by an instrument head that is attached to the upper end of a handle portion, enabling the instrument to be relatively compact and capable of being held for use in a single hand of the caregiver. The handle portion retains a source of power (e.g., a plurality of rechargeable batteries) for energizing a contained light source, such as an incandescent lamp or at least one LED, in order to provide sufficient light to the intended target (i.e., the eye), through a distal end of the instrument head. An optical or imaging system contained within the instrument head images the illuminated retina of the eye and directs that image to either an eyepiece or an electronic imaging element, which is disposed at the proximal end of the instrument head.
Fundus cameras, such as described by EP 1 138 255 A1, are a much more sophisticated diagnostic apparatus, as compared to ophthalmoscopes, that are also used for measuring and determining various conditions involving the eye. These latter devices are quite prohibitive in cost, as compared to typical ophthalmoscopes, and can often easily exceed $25,000. The optical systems incorporated in fundus cameras are considerably more intricate and complex than those used in ophthalmoscopes and are also much larger, typically requiring a patient to utilize a chin rest or similar configuration for purposes of stability when conducting an examination. Advantageously, these instruments are configured to provide a field of view of at least 30 to 40 degrees relative to a target of interest (i.e., the eye), which adds significant functionality and capability as compared to direct ophthalmoscopes, the latter usually having a more restricted field of view of only about 5 degrees. Having a larger field of view is essential for enabling more comprehensive diagnoses, such as diabetic retinopathy, to be reliably conducted. Diabetic retinopathy often has no early warning signs, but first stages can be detected by fundus photography in which microaneurysms (microscopic blood-filled bulges in the artery walls), as well as retinal ischemia (blocked or narrowing retinal blood vessels) indicative of the lack of blood flow can be readily and proactively detected.
Given the present state of healthcare reform, a general need exists to provide an eye viewing device, such as an ophthalmoscope, that can reliably provide a larger field of view in order to permit more comprehensive eye examinations to be conducted, but in lieu of a fundus camera.
To that end, there have been numerous attempts to design diagnostic instruments that enable a caregiver to view more of the fundus of the eye. The majority of these attempts has been realized, but by means of scanning the area of interest and not directly viewing the desired area all at once and/or requiring medication to also dilate the pupil of the eye. Pupil dilation creates a level of inconvenience and discomfort for the patient.
More recently, Applicants have developed a digital ophthalmoscope with a contained imaging system that is capable of producing about a 25 degree field of view, using panoramic imaging of the retina. In one version, a smartphone is mechanically supported to the rear of an instrument housing with the imager of the smartphone being positioned in alignment with the contained optical assembly of the instrument or in which the optical assembly is augmented to divert an image to the portable electronic device in order to directly receive captured images.
Still further, it would be advantageous to provide an ophthalmic instrument that provides greater versatility in regard to operation when used in conjunction with a portable electronic device, such as a smartphone or a tablet PC.
Therefore and according to a first aspect, there is provided an ophthalmic instrument comprising an imaging assembly having a defined imaging axis and an illumination assembly comprising a source of illumination and having a defined illumination axis, each of the illumination and optical assemblies being disposed within an instrument housing. The instrument including a imaging device wherein the source of illumination creates a focused illumination spot through the pupil that is off axis relative to the optical axis of the instrument and in which the imaging assembly is configured to enable a field of view of at least 40 degrees of the retina of a subject that is directed to the imaging device.
According to at least one version, the imaging system comprises an objective lens and a projection lens, each being disposed along the optical axis and in which the objective lens is sized in order to enable about a 40 degree field of view of the intended target.
According to one version, an imaging device is attachable to the instrument. In at least one embodiment a portable electronic device, such as a smartphone, having a contained electronic imaging element is directly aligned with the imaging assembly along the imaging axis of the instrument when the portable electronic device is attached thereto. According to another embodiment, an electronic imager is disposed within the ophthalmic instrument wherein the images received by the imager can be wirelessly transmitted to a portable electronic device, such as a smartphone or tablet PC, the latter being further configured to control the operation of the ophthalmic instrument. Through this latter form of connection, there is no requirement having to specifically align the imaging element of the portable electronic device with the imaging assembly of the instrument.
According to another version, there is provided a method for enabling increased capability in an ophthalmoscope, the method comprising the steps of:
providing an imaging assembly including an objective lens and a projection lens each disposed commonly along an imaging axis;
providing an illumination assembly having a source of illumination disposed along an illumination axis of the instrument and at least one optical element for causing illumination to be directed through the pupil of a patient's eye and off axis relative to the imaging axis of the instrument and in which a field of view of at least 40 degrees is produced by the imaging assembly and in which an imaging device is configured to receive images from the imaging assembly.
The objective lens is sized to enable the increased field of view wherein the off-axis alignment of the illumination assembly provides sufficient light as a point source to the target while reducing glare-related effects.
According to at least one version a portable electronic device, such as a smartphone, a tablet PC or other device having a contained electronic imager, can be disposed such that the contained imager is aligned along the imaging axis to receive a resulting image. Additional optical elements can be added to adapt to the imaging device, such as to increase magnification and resolution. In another version, an electronic imager can be disposed along the imaging axis to receive an image that can be transmitted wirelessly to a portable electronic device, such as smartphone or a tablet PC, which is either attached to the instrument or located in close proximity thereto.
One advantage provided is that of increased capability in which an ophthalmoscope, configured in the manner described herein, produces a significantly wider field of view to enable similar capabilities of prohibitively more expensive fundus cameras, such as diabetic retinopathy.
Another advantage realized is that enhanced examinations can take place in a doctor's office, enabling proactive diagnoses to be made and in which a field of view of at least 40 degrees can be achieved without medication to dilate the pupil of the eye.
Yet another advantage is that the herein described instrument can be connected and controlled by a portable electronic device that is either directly or indirectly attached to the instrument.
Still another advantage is that the resulting data can be streamed to a “Cloud” service, external peripheral devices, or remote clinical sites using custom software applications.
Yet another advantage is the ability to easily configure the solution to work as a portable instrument, or parked in a chin-rest stand (operated by a practitioner) or a binocular stand (operated by the patient).
These and other features and advantages will be readily apparent from the following Detailed Description, which should be read in conjunction with the accompanying drawings.
This description relates to certain exemplary embodiments of an ophthalmic instrument (i.e., an ophthalmoscope) that is configured to present a suitable (40) degree field of view of a target of interest (i.e., the eye), thereby enabling enhanced examinations to be conducted by a clinician, ophthalmologist, primary physician or other caregiver and as used in conjunction with at least one portable electronic device. It will be apparent that other versions can be created that include the inventive concepts described herein. In addition and throughout the course of this description, various terms are used in order to provide a suitable frame of reference with regard to the accompanying drawings. These terms, such as “distal”, “proximal”, “upper”, “lower”, “above”, “below”, “top”, “bottom”, “forward” and “backward” however, are not intended to specifically limit or otherwise narrow the scope of the invention, unless where expressly so indicated.
Referring to
An aperture stop 132 is disposed distally forward of the mirror 128 along the defined illumination axis 127 and through which light reflected from the mirror 128 is directed toward a target (i.e., the eye, shown herein schematically as 160) of interest, and as discussed herein. According to this embodiment, the aperture stop 132 has a spacing of approximately 1 mm in order to control the amount of reflected light passing therethrough.
According to this exemplary embodiment, the illumination assembly 120 further includes an objective lens 144 that is centered and aligned along an optical or imaging axis 158,
Referring to
Still referring to
A portable electronic imaging device 180 (shown schematically in
In terms of operation and according to this exemplary embodiment, illumination light rays, as shown in dashed lines 153, in the form of white light is emitted from the LED 124, reflected from the mirror 128 and directed through the aligned aperture stop 132 toward the distal end of the instrument 100. As noted, the directed light rays 153 passing through the objective lens 144 are focused by this lens 144 and pass through the pupil 162, the latter having a spacing of approximately 2 mm, as an illumination spot 138 that is disposed slightly off axis relative to the imaging axis 158 of the instrument 100. More specifically and according to this embodiment, the formed illumination spot 138 is approximately 1 mm from the imaging axis 158 wherein the illumination spot 138 is focused onto the cornea 163 of a patient's eye 160. Sufficient illumination is provided by the LED 124 to enable reflection of the light from the fundus (retina) of the eye 160.
A set of solid lines 154 depict imaging light rays wherein the reflected light includes an image of the fundus 164 of the eye 150, which is transmitted by outwardly projecting rays from the pupil 162 of the eye 160 as a cone of light through the objective lens 144 along the imaging axis 158 of the instrument 100. Referring to
As shown in the enhanced view at the proximal end of the imaging assembly 140 according to
While the prior two-lens imaging assembly is highly effective in creating a 40 degree field of view, improvements in resolution and/or magnification can be made. To that end and referring to
An enlarged view of the added proximal portion of the exemplary imaging assembly 210 is shown in
Yet another alternative version of an ophthalmoscope 300 is depicted in
As in the preceding exemplary embodiments that have been described, this ophthalmoscope 300 includes an illumination assembly 308 and an imaging assembly 310, each being disposed within the instrument housing (not shown). The illumination assembly 308 comprises a white or multi-color LED 312 that is configured to be mounted, for example, to a printed circuit board 313. As previously noted, the LED 312 can preferably emit an amber light capable of emitting a light having a wavelength of approximately 590 nm. An aperture stop 316 is disposed a predetermined distance in front of the LED 312 and aligned along a defined illumination axis 315, as shown in
Though not shown, light that is reflected from the angled surface 332 of the beamsplitter 330 is directed through a set of objective lenses 340 that combine to focus the light through the pupil of a patient's eye (not shown) and at an angle relative to the imaging axis 321 of the instrument 300. As in the preceding, the light reflected from the angled surface 332 is first directed through an aperture stop 350. The light passing through the objective lens 340 is narrowed and focused as an illumination spot on the cornea of the eye that is slightly offset laterally relative to the imaging axis 321 of the instrument 300. The remaining illumination directed through the beamsplitter 330 impinges upon a light sink or trap 356 in order to prevent back reflection or glare produced by the light source 312, condensing lenses 319 or beamsplitter 330. The light sink 356 is formed from a light absorbing material such as strongly absorbing glass, black paint or other suitable material.
Referring to
The aperture stop 350 is disposed between the objective lens 350 and the beamsplitter 330. According to this embodiment, the aperture stop 350 has an opening of approximately 27.8 mm to prevent the passage of stray light.
The imaging lenses 360 according to this specific embodiment are also defined by a pair of spaced lenses 362, 366, each of the lenses being aligned along the defined imaging axis 321 and in proximal relation to the beamsplitter 330. The first imaging lens 362 according to this embodiment is defined by a distal surface 363 having a radius of curvature of approximately 26.9 mm and a proximal surface 365 having a radius of curvature of approximately 19.1 mm. The second lens 366 is defined by a distal surface 367 having a radius of curvature of approximately 27.4 mm and a proximal surface 369 having a radius of curvature of approximately 55.2 mm. The outer diameter of the second lens 366 is approximately 20.8 mm wherein the first lens 362 has an axial length of approximately 4.5 mm and the second lens 366 has an axial length of approximately 7.0 mm in which an air gap 370 provided between the first and second lens 362, 366 provides a separation of approximately 2.4 mm.
The herein described imaging assembly 310 can be axially aligned with the contained camera 381 (shown schematically in
As in the preceding, the herein described illumination and imaging assemblies are configured in order to create at least a 40 degree field of view that can be suitably imaged and enable enhanced examinations, such as diabetic retinopathy, to be performed by a caregiver and viewed for example on the display 384 of the attached smartphone 380.
Yet another alternative exemplary embodiment is herein described schematically with reference to
As in the preceding embodiment, the illumination assembly of this instrument 400 can include an LED that emits white, amber or other colored light, an aperture stop and a set of condensing optics, each being aligned along a defined illumination axis. According to this exemplary embodiment, a beamsplitter 432 is axially aligned with each of the foregoing elements, the beamsplitter 432 having an angled surface 436 that is configured to direct light to the pupil 162 of a patient's eye 160 as an illumination spot (not shown). A light sink or trap 438 aligned with the beamsplitter 432 is configured to receive excess illumination that is transmitted through the beamsplitter 432. The light sink 438 is formed from a light absorbing material such as strongly absorbing glass, black paint or other suitable material and is configured to reduce the incidence of glare or back reflection in the instrument 400 from the light source 424 or beamsplitter 432.
The imaging assembly 440 according to this exemplary embodiment includes an objective lens doublet 442 that is disposed proximally (i.e., behind) the beamsplitter 432 and aligned along the defined imaging axis 453. The objective lens 442 is sized and configured to create a suitable field of view (40 degrees).
According to this embodiment, the imaging assembly 440 further includes a set of relay lenses 452 as well as a set of imaging lenses 460, respectively, each of the latter being linearly disposed along the imaging axis 453 proximal to the objective lens 440 and distally arranged in relation to an electronic imaging device 480, such as a CCD or a CMOS that can be attached to the proximal end of the instrument 400. The electronic imaging device 480 can be provided as part of a separate device, or can be integral to the instrument 400 itself, being preferably disposed in a proximal end of the instrument head (not shown) and aligned with the relay lens 452, imaging lens 460 and other optical components of the imaging assembly 440 along the defined imaging axis 453.
According to this embodiment, the beam splitter 432 is disposed distally forward of the objective lens 442 and along the imaging axis 453 of the instrument 400. The beam splitter 432 is aligned with the light source 424 and is angled approximately 40 degrees relative to the imaging axis 453, as depicted by arrows 458.
In use and referring to
As opposed to the previously described instrument and according to this version, a reflected image of the retina 164 is sequentially directed through the pupil 162 along the imaging axis 453 of the instrument 400, through the beamsplitter 432 and subsequently through the objective lens 442. This latter optical element 442 is appropriately sized to create a field of view of 40 degrees wherein the transmitted image is transmitted through a first retinal focal plane 449 and subsequently through the relay lens 452 and a second conjugate retinal focal plane 454 in which the relayed image is transmitted through the imaging lens 460 to the proximal end of the instrument 400 and according to this exemplary embodiment to an electronic imaging element 480, such as either directly made integral to the instrument 400 or as part of a smartphone or other portable imaging device.
Referring to
Yet another exemplary embodiment of an ophthalmic instrument 600 is provided with reference to
According to this embodiment, the imaging assembly 619 further includes a set of relay lenses 628 as well as a set of imaging lens 638, respectively, each of the latter components being linearly disposed along the defined imaging axis 640 and in proximal relation to the projection lens 626 and distally in relation to an electronic imaging device 660, such as a CCD or a CMOS that can be attached to the proximal end 612 of the instrument housing 604. For purposes of this embodiment, the electronic imaging device 660 can be provided as part of a separate device, or can be integral to the instrument 600 itself, the imaging device 660 being aligned with the relay lens 628 and imaging lens 638 along the defined imaging axis 640.
A window 644 manufactured from an optically transmissive material or a beamsplitter is further aligned along the imaging axis 640 of the instrument 600 between the objective lens 620 and the projection lens 626 with the window 644 being acutely angled in relation to an illumination array 650 that is disposed along an illumination axis 654 of the instrument 600. A plurality of LEDs, herein labeled as S1, S2 and S3 are defined in the illumination array 650, although the specific number of LEDs utilized can be easily varied. The LEDs according to this embodiment are disposed in a side by side fixedly mounted relation on a circuit board 655 or similar substrate, each LED being configured to emit an amber light having a wavelength of approximately 590 nm. An aperture mask 659 having a series of appropriate sized holes 661 is disposed onto the illumination array 650, the holes 661 being aligned with the corresponding LEDs S1, S2, S3 of the array 650, specifically guiding light to a projection lens 664, which is distally disposed along the defined illumination axis 654. As shown, light from the illumination array 650 is directed through the holes 661 in the aperture mask 659 and through the projection lens 664, the emitted light being reflected by the window 644 towards the objective lens 620. According to this embodiment, an infrared LED 670 is disposed adjacent the distal side 622 of the objective lens 620 in relation to an outer diametral portion thereof. An infrared photodiode 676 is also provided in relation to an outer diametral portion of the objective lens 620, the photodiode 676 being disposed on an opposite side of the imaging axis 640 relative to the infrared LED 670. Each of the infrared LED 670 and the photodiode 676 are inwardly angled toward the front panel of the instrument housing 604 at its distal end 608. According to this embodiment and as schematically shown, the photodiode 676 is electrically connected to a microcontroller 680, the latter being connected to the LED array 650 and the portable electronic device 660.
In operation, the infrared LED 670 and the photodiode 676 are positioned such that light from the infrared LED 670 can be directed to the eye 630 and more specifically the pupil 634 of the patient, with light being reflected from the pupil 634 to the photodiode 676 only if the instrument 600 is set at a predetermined working distance (Z), which according to this embodiment is approximately 25 mm. The infrared LED 670 and the photodiode 676 herein provide an LED fixation path prior to initiating light from the illumination array 650. According to this exemplary embodiment and if the instrument 600 is set at the correct working distance to the eye 630 (to the pupil 634 of the eye), a signal from the photodiode 676 indicative of the receipt of reflected light from the eye 630 is provided to the microcontroller 680 and the illumination array 650 is enabled for use. If the photodiode 676 fails to receive an adequate amount of reflected light indicative that the instrument 600 is either in excess or inside of the proper working distance, the LEDs S1, S2, S3 of the illumination array 650 are caused to blink or to produce another effect that can be visually perceived by the user of the instrument 600. Alternatively, the illumination array can be rendered inoperative until the proper working distance has first been established.
Once the proper working distance (Z) has been established, the illumination array 650 produces an amber or other appropriately colored light that is transmitted to the eye 630, as reflected by the window 644 and transmitted through the objective lens 620. Reflected light from the retina 636 at the back of the eye 630 is transmitted through the objective lens 620, having provided a 40 degree field of view in which the light is transmitted through a retinal image plane through the window 644, the projection lens 626 and the remainder of the imaging assembly 619 to the portable electronic device 660 in the manner previously discussed.
According to yet another exemplary embodiment and with reference to
According to this version, the wireless imager 788 can be a Sony QX10 or Sony QX100 camera or other wirelessly connected imaging device that is linked with the display of the smart device 760. The reception of a signal from the photodiode 776 is linked to the microcontroller 780, whose output can be shown on the display of the smart device 760, indicating an “out of range” or “in range” signal to the user. Given the application of the preview mode described herein, this specific instrument 700 is preferably a bench top apparatus as opposed to being used for hand-held operation.
It should be noted that each of the foregoing instrument or instrument system designs can commonly include a portable electronic device (e.g., a tablet PC, smartphone) that is integrated directly as part the imaging assembly of the herein described instrument or otherwise as an attached device, as shown for example in
The ophthalmic instrument 800 according to this exemplary embodiment is defined by a housing 804 having an interior that is appropriately sized for retaining a plurality of components, including an imaging assembly 819 that enables a 40 degree (or greater) field of view of the eye (not shown) of a patient, as previously discussed, the imaging assembly 819 including an objective lens 820 disposed at a distal end 808 of the instrument housing 804 and a projection lens 830, each aligned along a common imaging axis 840. A mobile electronic camera 860, such as a Sony QX10 or a Sony QX100 mobile camera, is further configured and aligned with the imaging assembly 819 along the defined imaging axis 840. The mobile electronic camera 860 is defined by an enclosure 864 having an interior 868 that is sized to retain an electronic imager 869 as well as a mechanism that enables dynamic optical focusing, the imager 869 being aligned to receive the images from the imaging assembly 819 and then wireless transmit the captured images to a portable electronic device 870, such as a smartphone or tablet PC, which is remotely located using a convenient communication protocol, such as Bluetooth. The enclosure 869 is further configured for releasable attachment to the front or distal side of the portable electronic device but since the images are wirelessly transmitted there is no requirement for optical alignment when the device is attached to the portable electronic device 870.
In this latter embodiment, the operation of the ophthalmic instrument 800, including the electronic mobile camera 860, can be controlled using software that is resident in the portable electronic device 870 such as through the user interface of the portable electronic device 870. Advantageously and according to this exemplary embodiment, the electronic imager contained within the portable electronic device 870 does not have to be aligned with the instrument 800, thereby providing additional versatility in which the portable electronic device 870 can be located remotely from the patient.
It will be readily apparent to those of sufficient skill that other modifications and variations are possible based on the inventive ambits described herein, as well as the appended claims.
This application claims priority pursuant to relevant portions of 35 U.S.C. § 119 to provisional application U.S. Ser. No. 61/890,618, filed Oct. 14, 2013, the entire contents of which are herein incorporated by reference.
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| Number | Date | Country | |
|---|---|---|---|
| 20150103317 A1 | Apr 2015 | US |
| Number | Date | Country | |
|---|---|---|---|
| 61890618 | Oct 2013 | US |
