site search

customers
Forgot your password?

Imagine Eyes - Adaptive optics, adapted to eye care

Imagine Eyes provides advanced ophthalmic devices for cellular-level retinal imaging, refractive diagnosis, and vision research.  Our products combine unequalled performance with wide-ranging functionalities to offer clinicians and researchers the technology they need to help preserve and improve vision. Click on the products below to learn more. To reach a salesperson, call us on +33 (0)1 64 86 15 66 or click here to contact us by e-mail.

rtx1™ Adaptive Optics Retinal Camera *   crx1™ Adaptive Optics Visual Simulator *
rtx1

The rtx1 Adaptive Optics Retinal Camera* is the first compact device that enables ophthalmologists to visualize the retina at the cellular-scale in vivo.
Learn more.

   crx1

The crx1 Adaptive Optics Visual Simulator* allows customers to simulate the effects of optical or surgical corrections on human vision in a completely non-invasive and reversible manner. Learn more.
     
AOKit™ - eye   irx3™ Wavefront Aberrometer **
aokit

The AOKit - eye is the ideal package for basic and industrial researchers that want to create their own adaptive-optics retinal imaging or vision simulation systems Learn more.

   irx3

The irx3 Wavefront Aberrometer provides high-precision analysis of refractive errors and accommodation over an extremely large dynamic range. Learn more.

News & upcoming events

(click here to read all the news)

Dr. K. Gocho-Nakashima presented AO study on GA at Euretina Winter

 Print E-mail
At the Euretina Winter Meeting in Rome on January 28, Dr. Kiyoko Gocho-Nahashima presented a poster showing how adaptive optics visualizes the progression of geographic atrophy at the cellular scale in dry AMD patients.

Coauthored with Dr. M. Uller, Pr. J-A. Sahel and Pr. M. Paques, the poster showcases the results on 8 subjects with GA, comparing images acquired with the rtx1 Adaptive Optics Retinal Camera* to those obtained using OCT and auto-fluorescence SLO in a clinical investigation setting. Several cases will be presented that show GA progression over time, revealing microscopic changes that are totally invisible to other imaging modalities.