Rapid measurement of individual cone photoreceptor pointing for evaluation of eye health using focus diversity

What is claimed is: 1. A method of measuring angular direction of individual photoreceptors in an eye, the method comprising: projecting a light from a light source through a pupil of the eye onto a retina of the eye; capturing an image of light reflected back from a plurality of photoreceptors at a first focal depth; capturing an image of light reflected back from the plurality of photoreceptors at a second focal depth, the second focal depth being different than the first focal depth; identifying at least one individual photoreceptor in the image captured at the first focal depth and in the image captured at the second focal depth; measuring a lateral difference of a position of the identified at least one individual photoreceptor between the image captured at the first focal depth and the image captured at the second focal depth; and calculating an angular direction of the at least one individual photoreceptor based on the measured lateral difference. 2. The method of claim 1 , wherein capturing an image of light reflected back from the plurality of photoreceptors includes capturing an image by an imaging device capable of imaging individual photoreceptors. 3. The method of claim 2 , wherein the imaging device is one selected from a group consisting of an optical-coherence tomography system, a scanning laser ophthalmoscope, and a fundus camera. 4. The method of claim 1 , further comprising changing the focal depth of an imaging device from the first focal depth to the second focal depth after capturing an image at the first focal depth and before capturing an image at the second focal depth. 5. The method of claim 4 , wherein changing the focal depth of the imaging device includes operating a controllably deformable mirror to change the focal depth of the imaging device from the first focal depth to the second focal depth. 6. The method of claim 4 , wherein changing the focal depth of the imaging device includes controllably operating a non-adaptive optics defocus mechanism selected from a group consisting of a linearly-movable lens, an electro-optic lens, a fluid-filled lens, and a liquid crystal device. 7. The method of claim 4 , further comprising: capturing a first plurality of images at the first focal depth; generating a first composite image from the first plurality of images captured at the first focal depth; capturing a second plurality of images at the second focal depth; and generating a second composite image from the second plurality of images captured at the second focal depth, wherein measuring the lateral difference of the position of the identified at least one individual photoreceptor includes identifying the lateral difference of the position of the identified at least one individual photoreceptor in the first composite image relative to the position of the identified at least one individual photoreceptor in the second composite image. 8. The method of claim 1 , further comprising capturing an image of light reflected back from a plurality of photoreceptors at more than two focal depths. 9. The method of claim 1 , further comprising: identifying a plurality of individual photoreceptors in the image captured at the first focal depth; identifying each photoreceptor of the plurality of photoreceptors in the image captured at the second focal depth; and measuring a lateral difference of a position of each photoreceptor of the plurality of individual photoreceptors between the image captured at the first focal depth and the image captured at the second focal depth. 10. The method of claim 1 , wherein identifying the at least one individual photoreceptor in the image captured at the first focal depth and in the image captured at the second focal depth includes performing a registration between the image captured at the first focal depth and the image captured at the second focal depth to identify the same individual photoreceptor in both the image captured at the first focal depth and the image captured at the second focal depth. 11. A system for detecting and measuring photoreceptor disarray, the system comprising: a source positionable to project light through a pupil of an eye onto a retina of the eye; an adjustable-focus imaging system configured to capture an image of light reflected back from a plurality of photoreceptors of the eye at a plurality of different focal depths; and an image processing system configured to identify an individual photoreceptor in an image captured by the adjustable-focus imaging system at a first focal depth of the plurality of focal depths, identify the same individual photoreceptor in an image captured by the adjustable-focus imaging system at a second focal depth of the plurality of focal depths, and measure a first lateral difference between a position of the individual photoreceptor in the image captured at the first focal depth and a position of the individual photoreceptor in the image captured at the second focal depth. 12. The system of claim 11 , wherein the image processing system further configured to identify a second individual photoreceptor in the image captured at the first focal depth, identify the same second individual photoreceptor in the image captured at the second focal depth, measure a second lateral difference between a position of the second individual photoreceptor in the image captured at the first focal depth and the position of the second individual photoreceptor in the image captured at the second focal depth, and evaluating photoreceptor disarray based on a comparison of the first lateral difference and the second lateral difference. 13. The system of claim 11 , wherein the adjustable-focus imaging system includes at least one imaging device selected from a group consisting of an optical-coherence tomography system, a scanning laser ophthalmoscope, and a fundus camera. 14. The system of claim 11 , wherein the adjustable-focus imaging system includes an adaptive optics component selected from a group consisting of a controllably deformable mirror and a controllably deformable lens, and wherein the adjustable-focus imaging system captures images at the plurality of different focal depths by operating the adaptive optics component to change the focal depth of the imaging system from the first focal depth to the second focal depth. 15. The system of claim 11 , wherein the adjustable-focus imaging system includes a lens, and wherein the adjustable-focus imaging system captures images at the plurality of different focal depths by controllably adjusting a position of the lens in a linear direction and capturing at least one image at each of a plurality of positions along the linear direction. 16. The system of claim 11 , wherein the image processing system is further configured to generate a first composite image from a first plurality of images captured by the adjustable-focus imaging system at the first focal depth, and generate a second composite image from a second plurality of images captured by the adjustable-focus imaging system at the second focal depth, wherein the image processing system is configured to measure the lateral difference of the position of the individual photoreceptor by identifying the lateral difference between a position of the individual photoreceptor in the first composite image and a position of the same individual photoreceptor in the second composite image. 17. The system of claim 11 , wherein the image processing system is further configured to measure a plurality of lateral differences in a position of the individual photoreceptor from a p