Artificial Retina and Artificial Iris

Number: 0713

Table Of Contents

Policy
Applicable CPT / HCPCS / ICD-10 Codes
Background
References

Policy

Scope of Policy

This Clinical Policy Bulletin addresses artificial retina and artificial iris.

  1. Experimental and Investigational

    Aetna considers the following interventions experimental and investigational because the effectiveness of these approaches has not been established:

    1. Artificial retina devices (e.g., the Argus II) because there is insufficient scientific evidence of the safety and effectiveness of these devices in restoring vision;
    2. Artificial iris devices (e.g., the CustomFlex Artificial Iris) for anterior segment reconstruction, and the treatment of aniridia, post-operative or traumatic aphakia, and other iris defects because of insufficient scientific evidence of their safety and effectiveness.
Table:

CPT Codes / HCPCS Codes / ICD-10 Codes
Code Code Description

CPT codes not covered for indications listed in the CPB:
0100T Placement of a subconjunctival retinal prosthesis receiver and pulse generator, and implantation of intra-ocular retinal electrode array, with vitrectomy
0472T Device evaluation, interrogation, and initial programming of intra-ocular retinal electrode array (eg, retinal prosthesis), in person, with iterative adjustment of the implantable device to test functionality, select optimal permanent programmed values with analysis, including visual training, with review and report by a qualified health care professional
0473T Device evaluation and interrogation of intra-ocular retinal electrode array (eg, retinal prosthesis), in person, including reprogramming and visual training, when performed, with review and report by a qualified health care professional
0616T Insertion of iris prosthesis, including suture fixation and repair or removal of iris, when performed; without removal of crystalline lens or intraocular lens, without insertion of intraocular lens
0617T     with removal of crystalline lens and insertion of intraocular lens
0618T     with secondary intraocular lens placement or intraocular lens exchange

HCPCS codes not covered for indications listed in the CPB:
C1839 Iris prosthesis [artificial iris devices]
C1841 Retinal prosthesis, includes all internal and external components
C1842 Retinal prosthesis, includes all internal and external components; add-on to C1841
L8608 Miscellaneous external component, supply or accessory for use with the argus ii retinal prosthesis system

ICD-10 codes not covered for indications listed in the CPB:
E08.311 - E08.39 Diabetes mellitus due to underlying condition with ophthalmic complications [retinopathy]
E09.311 - E09.39 Drug or chemical induced diabetes mellitus with ophthalmic complications [retinopathy]
E10.311 - E10.39 Type 1 diabetes mellitus with ophthalmic complications [retinopathy]
E11.311 - E11.39 Type 2 diabetes mellitus with ophthalmic complications [retinopathy]
E13.311 - E13.39 Other specified diabetes mellitus with ophthalmic complications [retinopathy]
H21.00 - H21.9 Other disorders of iris and ciliary body
H27.00 - H27.03 Aphakia [Post-operative or traumatic aphakia]
H31.101 - H31.129 Choroidal degeneration
H33.001 - H35.9 Retinal detachments and breaks, retinal vascular occlusions and other retinal disorders
Q13.0 Coloboma of iris
Q13.1 Absence of iris
Q13.2 Other congenital malformations of iris
Q13.81 Rieger's anomaly

Background

Artificial Retina

Researchers have been testing microelectronic retinal implants as a method of restoring vision in patients rendered blind by degenerative diseases of the retina such as retinitis pigmentosa (RP) and age-related macular degeneration (ARMD).  Tests of electrical stimulation of the retinal surface have demonstrated that such stimulation may induce light sensation.  These studies have shown that retinal neurons are preserved after death of photoreceptors in retinitis pigmentosa. 

Two types of retinal implant systems are under development:
  1. epiretinal implants, designed to communicate directly with the ganglion and bipolar cells; and
  2. subretinal implants, designed to replace photoreceptors in the retina. 

Both types of implants are intended to restore some vision through electrical stimulation of functional neurons in the retina.  Retinal implants require an intact optic nerve pathway to allow them to function.  Both systems translate incoming light, whether from a camera or the environment, to electrical stimulation of the functional neurons in the retina.

Epiretinal implants are positioned on the surface of the retina and receive light signals from external camera systems.  An electronic chip camera mounted in the frame of special glasses captures images and transmits the images via electrical impulses to a second chip, which is implanted in the retina.  Epiretinal implant systems may include other components such as image processing electronics, a telemetry system to provide power and data to the implanted subsystems, implanted electronics for signal decoding and stimulus generation, and an electrode array to deliver the electrical charge to the retina.

Subretinal implants are positioned behind the retina and receive light directly from the environment.  In this approach, light is converted into electrical signals that stimulate remnant cell layers of the retina. 

The first Argus retinal prosthesis was labeled the Argus 16 since it consisted of 16 electrodes attached to the back of the retina.  It was created by Second Sight Inc. (Sylmar, CA) as a means of restoring sight to the blind.  The Argus 16 device (also known as Argus I) was a complex arrangement of inter-connected devices.  Similar to the virtual sight devices, the Argus implant also used spectacles.  It consisted of a miniature camera and transmitter mounted in the rims of the spectacles, an implanted receiver that receives the output of that camera, as well as an electrode-studded array secured to the retina with a micro-tack.  A wireless microprocessor and battery pack worn on the belt powered the entire arrangement.   The principal difference between the Argus implant and virtual sight devices was that Argus connects to the retina, whereas virtual sight connects to the optic nerve directly.  As a consequence, the Argus implant requires a natural eyeball to still be in place, and cannot work with those lacking such.  The camera was capable of capturing images in far greater detail than the electrode array was capable of sending to the brain.  The 16 electrodes, arranged in a 4 X 4 pattern, could only produce a very tiny visual area, and literally a display of 4 pixels by 4 pixels, of the outside world.  Thus, the Argus implant only offer vague shadows and light impressions.  However, when compared with blindness, such ability may be beneficial.  In 2007, clinical trials began on the Argus I's replacement, the Argus II. 

Ahuja et al (2011) examined to what extent subjects implanted with the Argus II retinal prosthesis can improve performance compared with residual native vision in a spatial-motor task.  High-contrast square stimuli (5.85 cm sides) were displayed in random locations on a 19 inches (48.3 cm) touch screen monitor located 12 inches (30.5 cm) in front of the subject.  Subjects were instructed to locate and touch the square center with the system on and then off (40 trials each).  The coordinates of the square center and location touched were recorded.  A total of 96 % (26/27) of subjects reported a significant improvement in accuracy and 93 % (25/27) demonstrated a significant improvement in repeatability with the system on compared with off (p < 0.05, Student t test).  A group of 5 subjects that had both accuracy and repeatability values less than 250 pixels (7.4 cm) with the system off (i.e., using only their residual vision) was significantly more accurate and repeatable than the remainder of the cohort (p < 0.01).  Of this group, 4 subjects showed a significant improvement in both accuracy and repeatability with the system on.  The authors concluded that in a study on the largest cohort of visual prosthesis recipients to date, these investigators found that artificial vision augments information from existing vision in a spatial-motor task.

Weiland et al (2011) stated that degenerative diseases such as ARMD and RP primarily affect the photoreceptors, ultimately resulting in significant loss of vision.  Retinal prostheses aim to elicit neural activity in the remaining retinal cells by detecting and converting light into electrical stimuli that can then be delivered to the retina.  The concept of visual prostheses has existed for more than 50 years and recent progress shows promise, yet much remains to be understood about how the visual system will respond to artificial input after years of blindness that necessitate this type of prosthesis.  In this review, the authors focused on 3 major areas:
  1. the histopathologic features of human retina affected by ARMD and RP,
  2. current results from clinical trials, and
  3. challenges to overcome for continued improvement of retinal prostheses. 

They noted that "the routine nature of intraocular lens implantation today belies decades of hard-won surgical and biomaterial advances.  Retinal prostheses are following a similar roadmap, and to realize their full potential, we have to allow time not only for the clinical and biological testing, but also for engineering and technical advances".

In a single-arm, prospective, multi-center clinical trial, Humayun and colleagues (2012) evaluated the Argus II Retinal Prosthesis System (Second Sight Medical Products, Inc.,) in blind subjects with severe outer retinal degeneration.  A total of 30 subjects were enrolled in this study.  All subjects were followed-up for a minimum of 6 months and up to 2.7 years.  The electronic stimulator and antenna of the implant were sutured onto the sclera using an encircling silicone band.  Next, a pars plana vitrectomy was performed, and the electrode array and cable were introduced into the eye via a pars plana sclerotomy.  The microelectrode array then was tacked to the epiretinal surface.  The primary safety end points for the trial were the number, severity, and relation of serious adverse events (SAEs).  Principal performance end points were assessments of visual function as well as performance on orientation and mobility tasks.  Subjects performed statistically better with the system "on" versus "off" in the following tasks: object localization (96 % of subjects), motion discrimination (57 %), and discrimination of oriented gratings (23 %).  The best recorded visual acuity to date is 20/1,260.  Subjects' mean performance on orientation and mobility tasks was significantly better when the system was "on" versus "off"; 70 % of the patients did not have any SAEs.  The most common SAE reported was either conjunctival erosion or dehiscence over the extra-ocular implant and was treated successfully in all subjects except in 1, who required explantation of the device without further complications.  The authors concluded that the long-term safety results of Second Sight's retinal prosthesis system are acceptable, and most subjects with profound visual loss perform better on visual tasks with system than without it.  It is unclear whether these statistically better findings are translated into better clinical outcomes.  The results of this small feasibility study need to be validated by further investigations.

Barry and Dagnelie (2012) studied the capabilities of the Argus II retinal prosthesis for guiding fine hand movement, and demonstrated and quantified guidance improvement when using the device over when not using the device for progressively less predictable trajectories.  A total of 21 patients with RP, remaining vision no more than bare light perception, and an implanted Argus II epi-retinal prostheses used a touch-screen to trace white paths on black backgrounds.  Sets of paths were divided into 3 categories:
  1. right-angle/single-turn,
  2. mixed-angle/single-turn, and
  3. mixed-angle/two-turn. 

Subjects trained on paths by using prosthetic vision and auditory feedback, and then were tested without auditory feedback, with and without prosthetic vision.  Custom software recorded position and timing information for any contact that subjects made with the screen.  The area between the correct path and the trace, and the elapsed time to trace a path were used to evaluate subject performance.  For right-angle/single-turn sets, average tracing error was reduced by 63 % and tracing time increased by 156 % when using the prosthesis, relative to residual vision.  With mixed-angle/single-turn sets, error was reduced by 53 % and time to complete tracing increased by 184 %.  Prosthesis use decreased error by 38 % and increased tracing time by 252 % for paths that incorporated two turns.  The authors concluded that use of an epi-retinal visual prosthesis can allow RP patients with no more than bare light perception to guide fine hand movement visually.  Further, prosthetic input tends to make subjects slower when performing tracing tasks, presumably reflecting greater effort

Dorn et al (2013) investigated the ability of 28 blind subjects implanted with a 60-electrode Argus II (Second Sight Medical Products, Inc., Sylmar, CA) retinal prosthesis system to detect the direction of a moving object.  Blind subjects (bare light perception or worse in both eyes) with RP were implanted with the Argus II prosthesis as part of a phase 1/2 feasibility study at multiple clinical sites worldwide.  The experiment measured their ability to detect the direction of motion of a high-contrast moving bar on a flat-screen monitor in 3 conditions:

  1. with the prosthesis system on and a 1-to-1 mapping of spatial information,
  2. with the system off, and
  3. with the system on but with randomly scrambled spatial information. 

Fifteen subjects (54 %) were able to perform the task significantly better with their prosthesis system than they were with their residual vision, 2 subjects had significantly better performance with their residual vision, and no difference was found for 11 subjects.  Of the 15 better-performing subjects, 11 were available for follow-up testing, and 10 of them had significantly better performance with normal rather than with scrambled spatial information.   The authors concluded that these findings demonstrated that blind subjects implanted with the Argus II retinal prosthesis were able to perform a motion detection task they could not do with their native vision, confirming that electrical stimulation of the retina provides spatial information from synchronized activation of multiple electrodes.

On February 14, 2013, the Food and Drug Administration (FDA), under humanitarian device exemption (HDE), approved the Argus II Retinal Prosthesis System, the first implanted device to treat adult patients with advanced RP.  The device, which includes a small video camera, transmitter mounted on a pair of eyeglasses, video processing unit (VPU) and an implanted retinal prosthesis (artificial retina), replaces the function of degenerated cells in the retina and may improve a patient’s ability to perceive images and movement.  The VPU transforms images from the video camera into electronic data that is wirelessly transmitted to the retinal prosthesis.  An HDE exempts the device from a review of clinical effectiveness.  The FDA concluded the Argus II Retinal Prosthesis System will not expose blind individuals with severe outer retinal degeneration to an unreasonable or significant risk of illness or injury.  The FDA concluded the initial data demonstrated a probable benefit that out-weighed the risks of the device.

An UpToDate review on “Retinitis pigmentosa: Treatment” (Garg, 2013) states that “One retinal prosthesis system (Argus II) converts video images captured from a very small camera housed in the patient’s glasses, into a series of small electrical impulses that are wirelessly transmitted to an array of 60 electrodes on the retina.  Argus II was approved for use in Europe in 2011 and is undergoing review by the US Food and Drug Administration in 2012.  Newer generations of prostheses have increasingly more electrodes, with one in the development phase with over 1000 electrodes.  Retinal prostheses have the potential to enhance the quality of life of RP patients by aiding in object recognition, mobility, and independent living …. Experimental approaches to treatment for RP, under active investigation, include gene therapy, transplantation of fetal retinal cells or stem cells, and electronic retinal prostheses”.

Kotecha et al (2014) evaluated the reach-to-grasp performance of patients fitted with an epiretinal artificial retina device.  This was a hospital-based case series consisting of 6 patients fitted with the Argus II retinal prosthesis.  Participants were asked to reach out and pick up a high-contrast cuboid object with the prosthesis in the “On”, “Off” or “Scrambled” setting presented in a randomized order.  The “Scrambled” setting consisted of a random, scattered signal presented to the prosthesis.  The session was repeated after a 4- to 6-week period.  Hand movements were measured using motion detection cameras.  The number of successful object grasps was calculated.  The number of successful grasps was greater with the prosthesis in the “On” setting (visit 1: median [interquartile range] percentage success: “Off” = 0 [0 to 50] %, “On” = 69 [67 to 95] %, “Scrambled” = 59 [42 to 95] %; Friedman Chi-squared test statistic 6.5, p = 0.04; visit 2 median [IQR] percentage success: “Off” = 0 [0 to 25] %, “On” = 69 [53 to 100] %, “Scrambled” = 28 [13 to 63] %; Friedman Chi-squared test statistic 8.4, p = 0.02).  The authors concluded that the use of an electronic retinal prosthesis facilitated reach-and-grasp performance.  Moreover, they stated that further work should explore how performance can be improved with targeted rehabilitation.

Stronks and Dagnelie (2014) stated that visual prostheses are devices to treat profound vision loss by stimulating nerve cells anywhere along the visual pathway, typically with electrical pulses.  The Argus II implant, developed by Second Sight Medical Products (SSMP, Sylmar, CA), targets the retina and features 60 electrodes that electrically stimulate the surviving retinal neurons.  Of the approximately 20 research groups that are actively developing visual prostheses, SSMP has the longest track record.  The Argus II was the first visual prosthesis to become commercially available: it received the European conformity (Conformité Européenne [CE]) marking in March 2011 and FDA approval was granted in February 2013 for humanitarian use in the USA.  Meanwhile, the Argus II safety/benefit study has been extended for research purposes, and is still ongoing.

Luo and da Cruz (2014) stated that the Argus® II is the first retinal prosthesis approved for the treatment of patients blind from RP, receiving CE marking in 2011 and FDA approval in 2013.  Alpha-IMS followed closely and obtained CE marking in July 2013.  Other devices are being developed, some of which are currently in clinical trials.  These investigators performed a systematic literature search on PubMed, Google Scholar and IEEExplore.  Retinal prostheses play a part in restoring vision in blind RP patients providing stable, safe and long-term retinal stimulation.  However, objective improvement in visual function does not always translate into consistent improvement in the patient's quality of life.  Controversy exists over the use of an external image-capturing device versus internally placed photo-diode devices.  The authors concluded that improvement in retinal prosthetic vision depends on:
  1. improving visual resolution,
  2. improving the visual field,
  3. developing an accurate neural code for image processing, and
  4. improving the biocompatibility of the device to ensure longevity.


Chuang et al (2014) noted that retinal implants present an innovative way of restoring sight in degenerative retinal diseases. Previous reviews of research progress were written by groups developing their own devices.  This systematic review objectively compared selected models by examining publications describing 5 representative retinal prostheses:
  1. Argus II,
  2. Boston Retinal Implant Project,
  3. Epi-Ret 3,
  4. Intelligent Medical Implants (IMI), and
  5. Alpha-IMS (Retina Implant AG).

 Publications were analyzed using 3 criteria for interim success:

  1. clinical availability,
  2. vision restoration potential and
  3. long-term biocompatibility. 

Argus II is the only device with FDA approval.  Argus II and Alpha-IMS have both received the European CE marking.  All others are in clinical trials, except the Boston Retinal Implant, which is in animal studies.  Resolution theoretically correlates with electrode number.  Among devices with external cameras, the Boston Retinal Implant leads with 100 electrodes, followed by Argus II with 60 electrodes and visual acuity of 20/1262.  Instead of an external camera, Alpha-IMS uses a photo-diode system dependent on natural eye movements and can deliver visual acuity up to 20/546.  IMI offers iterative learning; Epi-Ret 3 is a fully intra-ocular device; Alpha-IMS uses intra-ocular photo-sensitive elements.  Merging the results of these 3 criteria, Alpha-IMS is the most likely to achieve long-term success decades later, beyond current clinical availability.

Currently, there is insufficient evidence that the use of artificial retina devices result in improved useful vision.  Available data are limited to small, short-term, feasibility studies.  Furthermore, no professional medical society has recommended the use of artificial retina devices.

The Australian Safety and Efficacy Register of New Interventional Procedures – Surgical (ASERNIP-S)’s Technology Brief on “Argus II Retinal Prosthesis System for peripheral retinal degeneration” (2013) stated that “The evidence on the safety and effectiveness of the Argus II Retinal Prosthesis System considered in this Technology Brief is of a low level, being derived from the same group of 30 patients enrolled in the same phase two clinical trial.  Given that the device is in its initial stage of assessment and the studies included in this Technology Brief are derived from the first clinical trial to assess the safety and efficacy of the device, the initial results are promising …. Although the results from the studies included in this Technology Brief were promising, they were all derived from the same multicentre, phase II clinical trial of only 30 patients.  HealthPACT therefore recommend that this technology be monitored for 24 months, in which time additional evidence may become available”.

In an interventional case-series study, Rizzo et al (2014) studied the anatomic and functional outcomes of Argus II Retinal Prosthesis System implantation in patients with RP.  The study population included 6 patients with visual acuity (VA) no better than light perception.  After the Argus II Retinal Prosthesis System was implanted, complications and anatomic and functional results were studied.  The main outcome measures were mobility, square localization, direction of motion, grating VA, and Goldmann visual field, all of which were assessed.  Optical coherence tomography (OCT) was performed.  Implantation of the Argus II Retinal Prosthesis System was safely performed in all patients.  One patient experienced post-operative elevation in intra-ocular pressure (IOP), which was controlled medically.  In 1 patient, moderate detachment of the choroid occurred post-operatively, and it resolved spontaneously.  One patient withdrew from the study.  Wound dehiscence, endophthalmitis or retinal detachment was not observed.  All patients were able to locate a bright light on the ceiling and a dark line on the floor after the surgery.  Performance in square localization tests improved in 4 patients, and direction of motion improved in 3 patients; 1 patient achieved grating VA.  Goldmann visual field test results improved in all patients.  The authors concluded that patients showed improvement in visual tasks after the surgery, and the device was well-tolerated and functional over a 1-year follow-up period.  They stated that a rigorous patient-selection process is necessary to maximize patient compliance with the rigorous follow-up testing schedule.  Both patients and medical staff should be prepared for a lengthy, arduous rehabilitation process.  While the results of this small case-series study (n = 6) are promising, prospective randomized trials with long-term follow-up are needed to ascertain the safety and effectiveness of retinal prosthetic devices.

Sabbah et al (2014) explored the visual environment through head-scanning movements in subjects fitted with a retinal prosthesis connected to a head-mounted camera (camera-connected prosthesis [CC-P]).  As eye and camera misalignment might alter the spatial localization of images generated by the device, these researchers investigated if such misalignment occurred in blind subjects wearing a CC-P and whether it impacted spatial localization, even years after the implantation.  These investigators studied 3 subjects blinded by RP, fitted with a CC-P (Argus II) 4 years earlier.  Eye/head movements were video recorded as subjects tried to localize a visual target.  Pointing coordinates were collected as subjects were requested to orient their gaze toward pre-determined directions, and to point their finger to the corresponding perceived spot locations on a touch screen.  Finally, subjects were asked to give a history of their everyday behavior while performing visually controlled grasping tasks.  Misaligned head and gaze directions occurred in all subjects during free visual search.  Pointing coordinates were collected in 2 subjects and showed that median pointing directions shifted toward gaze direction.  Reportedly all subjects were unable to accurately determine their eye position, and they developed adapted strategies to perform visually directed movements.  The authors concluded that eye position affected perceptual localization of images generated by the Argus II prosthesis, and consequently visuo-motor coordination, even 4 years following implantation.  Affected individuals developed strategies for visually guided movements to attenuate the impact of eye and head misalignment.   These observations provided indications for rehabilitation procedures and for the design of upcoming retinal prostheses.

Weiland and Humayun (2014) stated that retinal prosthesis has been translated from the laboratory to the clinic over the past 20 years.  Currently, 2 devices have regulatory approval for the treatment of RP.  These devices provide partial sight restoration and patients use this improved vision in their everyday lives.  The authors noted that improved mobility and object detection are some of the more notable findings from the clinical trials.  However, significant vision restoration will require both better technology and improved understanding of the interaction between electrical stimulation and the retina.

In a multi-center, single-arm, prospective clinical trial, Ho and co-workers (2015) evaluated the safety, reliability, and benefit of the Argus II Retinal Prosthesis System in restoring some visual function to subjects completely blind from RP. These investigators reported clinical trial results at 1 and 3 years after implantation.  There were 30 subjects in 10 centers in the United States and Europe.  Subjects served as their own controls, that is, implanted eye versus fellow eye, and system on versus system off (native residual vision).  The Argus II System was implanted on and in a single eye (typically the worse-seeing eye) of blind subjects.  Subjects wore glasses mounted with a small camera and a video processor that converted images into stimulation patterns sent to the electrode array on the retina.  The primary outcome measures were safety (the number, seriousness, and relatedness of AEs) and visual function, as measured by 3 computer-based, objective tests.  A total of 29 of 30 subjects had functioning Argus II Systems implants 3 years after implantation; 11 subjects experienced a total of 23 serious device- or surgery-related AEs.  All were treated with standard ophthalmic care.  As a group, subjects performed significantly better with the system on than off on all visual function tests and functional vision assessments.  The authors concluded that the 3-year results of the Argus II trial support the long-term safety profile and benefit of the Argus II System for patients blind from RP.  They noted that earlier results from this trial were used to gain approval of the Argus II by the FDA and a CE mark in Europe.

Garcia and associates (2015) examined if blind individuals treated with a retinal prosthesis could also benefit from using the resultant new visual signal together with non-visual information when navigating. A total of 4 patients (blind for 15 to 52 years) implanted with the Argus II retinal prosthesis, and 5 age-matched and 6 younger controls, participated.  Subjects completed a path reproduction and a triangle completion navigation task, using either an indirect visual landmark and non-visual self-motion cues or non-visual self-motion cues only.  Control subjects wore goggles that approximated the field of view and the resolution of the Argus II prosthesis.  In both tasks, control subjects showed better precision when navigating with reduced vision, compared to without vision. Patients, however, did not show similar improvements when navigating with the prosthesis in the path reproduction task, but two patients did show improvements in the triangle completion task.  Additionally, all patients showed greater precision than controls in both tasks when navigating without vision.  The authors concluded that these findings indicated that the Argus II retinal prosthesis may not provide sufficiently reliable visual information to improve the precision of patients on tasks, for which they have learnt to rely on non-visual senses.

Gekeler and colleagues (2015) noted that electrical stimulation (ES) has a long history in ophthalmology. Sub-threshold ES can have beneficial therapeutic effects on hereditary degenerative retinal diseases.  Supra-threshold stimulation is able to elicit visual perceptions and, if multi-electrode fields are arranged as an array, usable pictures can be perceived by blind patients.  These investigators reviewed the current situation and studies on therapeutic trans-corneal ES.  Moreover, they discussed challenges, surgical concepts and visual results of active retinal implants.  These researchers provided an overview on trans-corneal ES and active retinal implants based on published results, with special emphasis on the clinical application.  The results of initial controlled studies on therapeutic trans-corneal ES in hereditary retinal diseases were very promising.  The largest controlled study so far in patients with RP has yielded many positive trends and some significant improvements in electrophysiological data.  Currently, 2 retinal implants have regulatory approval, the Argus II retinal prosthesis system and the Alpha-IMS.  Both systems can be used to improve visual perception and under test conditions can achieve visual acuities of 0.02 and 0.04, respectively.  The authors concluded that in-depth analyses and follow-up studies in larger patient groups are currently planned to definitively clarify the potential of therapeutic trans-corneal ES in RP patients.  They stated that the challenges of currently available active retinal implants are the technical bio-stability and the limited spatial resolution.

Luo and da Cruz (2016) stated that the Argus II Retinal Prosthesis System is the first prosthetic vision device to obtain regulatory approval in both Europe and the United States. As such it has entered the commercial market as a treatment for patients with profound vision loss from end-stage outer retinal disease, predominantly RP.  To-date, over 100 devices have been implanted worldwide, representing the largest group of patients currently treated with visual prostheses.  The system works by direct stimulation of the relatively preserved inner retina via epi-retinal microelectrodes, thereby replacing the function of the degenerated photoreceptors.  Visual information from a glasses-mounted video camera is converted to a pixelated image by an external processor, before being transmitted to the microelectrode array at the macula.  Elicited retinal responses are then relayed via the normal optic nerve to the cortex for interpretation.  These investigators reviewed the animal and human studies that led to the development of the Argus II device.  A sufficiently robust safety profile was demonstrated in the phase I/II clinical trial of 30 patients.  Improvement of function in terms of orientation and mobility, target localization, shape and object recognition, and reading of letters and short unrehearsed words have also been shown.  There remains a wide variability in the functional outcomes among the patients and the factors contributing to these performance differences are still unclear.  They stated that future developments in terms of both software and hardware aimed at improving visual function have been proposed; further experience in clinical outcomes is being acquired due to increasing implantation.

Seitz and colleagues (2016) stated that in ophthalmology, regenerative medicine is rapidly becoming a reality.  Cell-based therapeutic strategies in end-stage retinal degeneration may be of therapeutic value, whatever the mechanism of disease mechanismm.  However, while corneal transplantation is commonly performed with excellent results, many obstacles must be overcome before retinal transplants can become clinically useful.  The major problems are the production of appropriate transplants and functional integration in-situ.  New technologies allow the production of autologous transplants by inducing pluripotency in adult somatic cells.  The authors concluded that driven by this development, exciting new research has been conducted on the development of artificial retinal tissue for basic research and transplantation.

Pei and associates (2016) noted that retinal prosthesis offers a potential treatment for individuals suffering from photoreceptor degeneration diseases.  Establishing biological retinal models and simulating how the biological retina convert incoming light signal into spike trains that can be properly decoded by the brain is a key issue.  Some retinal models have been presented, ranking from structural models inspired by the layered architecture to functional models originated from a set of specific physiological phenomena.  However, most of these focused on stimulus image compression, edge detection and reconstruction, but did not generate spike trains corresponding to visual image.  In this study, based on state-of-the-art retinal physiological mechanism, including effective visual information extraction, static non-linear rectification of biological systems and neurons Poisson coding, a cascade model of the retina including the out plexiform layer for information processing and the inner plexiform layer for information encoding was brought forward, which integrated both anatomic connections as well as functional computations of retina.  Using MATLAB software, spike trains corresponding to stimulus image were numerically computed by 4r steps:
  1. linear spatiotemporal filtering, (ii) static non-linear rectification,
  2. radial sampling, and (iv) Poisson spike generation.  

The authors concluded that the simulated findings suggested that such a cascade model could recreate visual information processing and encoding functionalities of the retina, which is helpful in developing artificial retina for the retinally blind.

Duncan and colleagues (2017) reported the change in quality of life (QOL) after treatment with the Argus II epiretinal prosthesis in patients with end-stage RP.  The Vision and QOL Index (VisQOL) was used to assess changes in QOL dimensions and overall utility score in a prospective 30-patient single-arm clinical study.  VisQOL is a multi-attribute instrument consisting of 6 dimensions (injury, life, roles, assistance, activity and friendship) that may be affected by visual impairment.  Within each dimension, patients were divided into 2 groups based on how much their QOL was affected by their blindness at baseline (moderate/severe or minimal).  Outcomes were compared within each dimension sub-group between baseline and the combined follow-up periods using the Friedman test.  In addition, data from the 6 dimensions were combined into a single utility score, with baseline data compared to the combined follow-up periods.  Overall, 80 % of the patients reported difficulty in 1 or more dimensions pre-implant.  Composite VisQOL utility scores at follow-up showed no statistically significant change from baseline; however, in 3 of the 6 VisQOL dimensions (injury, life and roles), patients with baseline deficits showed significant and lasting improvement after implantation with Argus II.  In 2 of the 3 remaining dimensions (assistance and activity), data trended toward an improvement.  In the final VisQOL dimension (friendship), none of the patients reported baseline deficits, suggesting that patients had largely adjusted to this attribute.  The authors concluded that patients whose vision negatively affected them with respect to 3 VisQOL dimensions (i.e., getting injured, coping with the demands of their life and fulfilling their life roles) reported significant improvement in QOL after implantation of the Argus II retinal prosthesis.  Furthermore, the benefit did not deteriorate at any point during the 36-month follow-up, suggesting a long-term, durable improvement.

The authors noted that the drawbacks of this study included the small sample size (n = 30), reflecting the rarity of RP and limited patient information available at baseline for use as possible co-variates (including the level of previous rehabilitation, training and support).  In particular, understanding the extent of prior rehabilitation would have been helpful in explaining the disparity in baseline utility and domain scores, although this would not have affected the change in QOL scores after treatment.  They stated that it is unlikely that any single outcome measure represented a full picture of the benefit of the Argus II system for any particular patient.  It is important to note that the VisQOL was one of a battery of visual function and functional vision outcome measures used in this clinical trial, all of which together showed an overall trend of benefit from the Argus II system.

Cheng and co-workers (2017) noted that to-date, reviews of retinal prostheses have focused primarily on devices undergoing human trials in the Western Hemisphere and failed to capture significant advances in materials and engineering research in countries such as Japan and Korea, as well as projects in early stages of development.  To address these gaps, this systematic review examined worldwide advances in retinal prosthetic research, evaluated engineering characteristics and clinical progress of contemporary device initiatives, and identified potential directions for future research in the field of retinal prosthetics.  These researchers carried out a literature search using PubMed, Google Scholar, and IEEExplore following the PRISMA guidelines for systematic review.  Inclusion criteria were peer-reviewed papers demonstrating progress in human or animal trials and papers discussing the prosthetic engineering design.  For each initiative, a description of the device, its engineering considerations, and recent clinical results were provided.  A total of 10 prosthetic initiatives met inclusion criteria and were organized by stimulation location.  Of these initiatives, 4 have recently completed human trials, 3 are undergoing multi- or single-center human trials, and 3 are undergoing pre-clinical animal testing.  Only the Argus II (FDA 2013, CE 2011) has obtained FDA approval for use in the US; the Alpha-IMS (CE 2013) has achieved the highest VA using a Landolt-C test to-date and is the only device presently undergoing a multi-center clinical trial.  The authors concluded that several distinct approaches to retinal stimulation have been successful in eliciting visual precepts in animals and/or humans.  However, many clinical needs are still not met and engineering challenges must be addressed before a retinal prosthesis with the capability to fully and safely restore functional vision can be realized.

Furthermore, an UpToDate review on ‘” (Garg, 2017) states that “Retinal prosthesis -- Devices are being tested that transduce light into electrical signals and transmit this information directly to the inner retina (bypassing the diseased outer retina of RP), optic nerve, or occipital visual cortex.  Patients involved in studies of these devices have reported seeing flashes of light and have been able to sense motion, locate large objects, and recognize large letters.  There are multiple retinal prostheses in clinical trials.  One retinal prosthesis system (Argus II) converts video images captured from a very small camera housed in the patient’s glasses, into a series of small electrical impulses that are wirelessly transmitted to an array of 60 electrodes on the retina.  Vision restoration is theoretically correlated with the number of electrodes.  Newer generations of prostheses have increasingly more electrodes, with one in the development phase with over 1000 electrodes.  Retinal prostheses have the potential to enhance the quality of life of RP patients by aiding in object recognition, mobility, and independent living”.

Farvardin and associates (2018) noted that over the past few years, visual prostheses (namely, Argus II retinal implant) and gene therapy have obtained FDA approval in treating blindness resulting from RP.  Compared to gene therapy; Argus II is less costly with a demonstrated favorable outcome, though the vision is yet artificial.  To obtain better results, expectation counseling and pre-operative retinal assessment are critical.  The global experience with Argus II has enrolled no more than 300 cases so far.  The first Argus II retinal prosthesis in Iran was successfully implanted in Shiraz (October 2017).  To-date, Argus II artificial retina is implanted in 4 patients in Iran.  Beside successful surgery and post-operative care, rehabilitation efforts with validated outcome measures including visual rehabilitation together with neuro-visual, visuo-constructive and cognitive rehabilitation/empowerment approaches are expected to boost the functional outcome.  A multi-disciplinary approach within a cross-functional team would optimize strategies toward better patient outcomes.  As such, establishing a collaborative network will foster organized research efforts to better define outcome assessment and rehabilitation strategies.  These investigators attempted to provide an overview of Argus-II retinal implant global experience as well as the clinical outcome of the so far cases in Iran.  They stated that the working-team concept is crucial to success in many multi-disciplinary medical projects and the Retinal Prosthesis team is perhaps a typical example.  Synergizing efforts made by vitreo-retinal surgeons, medical engineers, rehabilitation experts, clinical and cognitive neuroscientists, and industry representatives would help moving toward more promising results.  These researchers stated that practitioners need to ensure that the patient selection for device implantation fulfills the eligibility criteria including patient's motivations, expectations, cognitive and communication capabilities as well as physical abilities to receive benefit from the device.  Key potentials for continued research toward improving the Argus-II vision through device optimization and advanced programing as well as neuro-visual, visuo-constructive and cognitive rehabilitation make the present time a critical turning-point for retinal prosthetic systems such as artificial retina to drive even-better future outcomes.

Golden and colleagues (2019) stated that the nature of artificial vision with a retinal prosthesis, and the degree to which the brain can adapt to the unnatural input from such a device, are poorly understood.  Thus, the development of current and future devices may be aided by theory and simulations that help to infer and understand what prosthesis patients see.  These researchers presented a biologically-informed, extensible computational framework to predict visual perception and the potential effect of learning with a subretinal prosthesis.  The framework relies on optimal linear reconstruction of the stimulus from retinal responses to infer the visual information available to the patient.  A simulation of the physiological optics of the eye and light responses of the major retinal neurons was used to calculate the optimal linear transformation for reconstructing natural images from retinal activity.  The result was then used to reconstruct the visual stimulus during the artificial activation expected from a subretinal prosthesis in a degenerated retina, as a proxy for inferred visual perception.  Several simple observations revealed the potential utility of such a simulation framework.  The inferred perception obtained with prosthesis activation was substantially degraded compared to the inferred perception obtained with normal retinal responses, as expected given the limited resolution and lack of cell type specificity of the prosthesis.  Consistent with clinical findings and the importance of cell type specificity, reconstruction using only ON cells, and not OFF cells, was substantially more accurate.  Finally, when reconstruction was re-optimized for prosthesis stimulation, simulating the greatest potential for learning by the patient, the accuracy of inferred perception was much closer to that of healthy vision.  The authors concluded that the reconstruction approach provided a more complete method for examining the potential for treating blindness with retinal prostheses than has been available previously.  It may also be useful for interpreting patient data in clinical trials, and for improving prosthesis design.

Artificial Iris for the Treatment of Iris Defects (Including Aniridia, Iris Melanotic Lesion Excision, Ocular Trauma, and Urrets-Zavalia Syndrome) and Post-Operative/Traumatic Aphakia

Aniridia (partial or total absence of iris) can be congenital or traumatic in etiology.  Congenital aniridia is a rare genetic disorder, which affects approximately 1 in 50,000 to 100,000 individuals in the United States.  Since the iris regulates the amount of light entering the eye, individuals with aniridia are sensitive to light and may lead to glare disability and other visual disturbances

Rickmann and colleagues (2016) noted that the custom-made, flexible artificial iris developed by HumanOptics and Koch can reconstruct the anterior segment of patients with aniridia.  In a retrospective, interventional case-series study, these researchers evaluated the long-term clinical outcome and complication spectrum following artificial iris implantation and the role of the embedded fiber mesh in view of specific complications.  Patients received an artificial iris between 2004 and 2013.  Only eyes with a minimum follow-up period of 2 years were included.  Indications were congenital, traumatic, or iatrogenic aniridia.  The artificial iris was used either with or without embedded fiber mesh for partial or full prostheses.  These investigators included 34 patients (mean age of 48.8 years; standard deviation [SD] ± 17.2) with a mean follow-up of 50.0 months (SD ± 18.9 months).  No re-positioning of prostheses was necessary.  In cases of keratopathy (17.6 %), visual function increased from baseline mean 1.6 logMAR (SD ± 0.7) to 1.2 logMAR (SD ± 0.7) after artificial iris implantation.  The remaining iris tissue darkened during the follow-up in 23.5 % (83.3 % with and 10.7 % without mesh), 8.8 % developed glaucoma (50 % with and 0 % without mesh) and 14.7 % needed consecutive surgery after prostheses implantation (50 % with and 7.1 % without mesh).  In 3 out of 7 trauma cases (42.9 %), silicone oil was spilled into the anterior chamber after 2.5 years on average.  The authors concluded that the artificial iris prosthesis revealed a good clinical outcome in terms of long-term stability, cosmetic appearance, visual function, and represented a good functional iris diaphragm for compartmentalization.  Complications such as glaucoma, darkening of iris tissue, and need for consecutive anterior segment surgery were clearly associated with implants with integrated fiber mesh, but not to those without.  Hence, the use of full iris prostheses without embedded fiber mesh, even in cases with remnant iris, and the use of slightly smaller implants than officially recommended may be beneficial.

Weissbart and Ayres (2016) examined the advantages and limitations of the various iris prostheses for the treatment for aniridia.  Multiple prosthetic iris devices have been developed for implantation in eyes with aniridia.  However, none is currently approved for use in the United States.  Therapeutic options include colored contact lenses, corneal tattooing, and corneal stromal implants, although these carry significant risks of infection and corneal scarring.  Prosthetic iris devices can often simultaneously treat aphakia or cataract as well as aniridia, and various models are currently available around the world from Morcher GMBH (Stuttgart, Germany), Ophtec USA Inc. (Boca Raton FL) and HumanOptics (Erlangen, Germany).  Surgical planning and technique are important in optimizing the safety of these devices.  The CustomFlex iris prosthesis from HumanOptics can be implanted within the capsular bag or ciliary sulcus with scleral fixation and offers excellent cosmetic outcomes.  At present, the HumanOptics prosthetic iris is being investigated in a multi-center clinical trial

In a retrospective study, Mostafa and associates (2018) discussed the limitations and benefits of the BrightOcular prosthetic artificial iris device in management of aniridia associated with aphakia or cataract.  This trial included 5 eyes of 4 patients who underwent implantation of the BrightOcular iris prosthesis (Stellar Devices) for total or partial aniridia.  The cases included 2 eyes of 1 patient with congenital aniridia associated with congenital cataract and 3 eyes with traumatic aniridia: 1 with subluxated cataractous lens and 2 with aphakia.  In all cases, the iris prosthesis was implanted after a 3-piece acrylic intra-ocular lens (IOL) was implanted.  These researchers evaluated the clinical course with a minimum follow-up period of 6 months, the intra-operative and post-operative complications, and the cosmetic satisfaction of patients.  All patients had improved uncorrected distance VA and best-corrected distance visual acuity (BCVA).  All patients had a transient corneal edema that resolved within the 1st post-operative week.  Only the patient with congenital aniridia had a permanent increase in IOP and developed a band keratopathy throughout a 2-year follow-up period.  The prosthesis was well-centered in all eyes except for 1 case that needed scleral suture fixation after 3 months.  All patients had a satisfactory cosmetic appearance.  The authors concluded that the BrightOcular iris prosthesis was a safe and useful tool to correct aniridia associated with pseudophakia or aphakia.  Being foldable, it was easy to be implanted through a small incision and placed in the ciliary sulcus without sutures when properly sized.  Cosmetic results were satisfactory; and sizing methods should be improved.  These researchers stated that more research should be performed to determine the best means of sizing the implant and to address the problem of post-operative IOP rise; and further studies should also examine the safety of the prosthesis in clear phakic eyes.  This was a small (n = 3 with traumatic aniridia), retrospective study; its findings need to be validated by well-designed studies

On May 30, 2018, the FDA approved the CustomFlex Artificial Iris (Clinical Research Consultants, Inc., Cincinnati, OH).  The CustomFlex Artificial Iris is a custom-made prosthetic iris made of thin, foldable medical-grade silicone.  It can be sized and colored for individual patients.  The CustomFlex Artificial Iris can be used to treat congenital and traumatic aniridia.  It can also be used to treat iris defects due to other conditions (e.g., albinism, or surgical excision due to uveal melanoma).  However, available evidence on the use of artificial iris for the treatment of aniridia is weak

Yoeruek and Bartz-Schmidt (2019) presented a new surgical technique for treating corneal opacity and aniridia with aphakia and the results in a small consecutive case series.  A 3-piece acrylic IOL was attached to a customized silicone iris prosthesis and fixed with 3 10-0 polypropylene sutures in a knotless technique using Z-sutures after trephination of the recipient cornea.  The medical records of all consecutive patients who had received a keratoplasty and an implantation of an artificial iris and IOL were reviewed; 5 eyes of 5 patients were included in the analysis.  The mean age of the patients was 46.2 years and the mean follow-up was 24.6 months.  The mean BCVA improved from 1.36 logMAR before surgery to 0.78 logMAR after surgery during the follow-up.  At the last follow-up visit, the artificial iris-IOL complex was well-centered with good positioning in all cases.  The authors concluded that management of post-traumatic aniridia combined with aphakia and corneal scars or graft failure by haptic fixation of a foldable IOL on an artificial iris combined with a simultaneous keratoplasty appeared to be a promising approach, which allowed to correct a complex lesion with a less traumatic and faster procedure.

In a single-center, case-series study, Mayer and colleagues (2019) examined the effect of an artificial iris implant on the remnant iris (n = 42 consecutive patients).  Morphologic evaluation was carried out over 24 ± 14 months.  Main outcome measures included remnant pupillary aperture, iris color, VA, IOP, and endothelial cell count (ECC).  In 7 of 42 cases (16.7 %), the residual iris aperture dilated from 36.6 ± 15.4 mm2 pre-operatively to 61.1 ± 12.5 mm 2 1 year post-operatively (66.9 % increase).  In 5 of 7 affected eyes the artificial iris had been implanted into the ciliary sulcus; in 2 eyes it had been sutured to the sclera; 4 of the 7 patients presented with remarkable complications: 2 eyes needed glaucoma shunt surgeries owing to pigment dispersion; 1 suffered from recurrent bleedings; and in 1 case artificial iris explantation was performed owing to chronic inflammation.  Anterior chamber depth (ACD) and angle, ECC, and VA did not change in this cohort.  Changes in color were not observed in the remnant iris.  The authors concluded that the implantation of an artificial iris prosthesis could lead to a residual iris retraction syndrome.  It was likely that residual iris was trapped in the fissure between the artificial iris and the anterior chamber angle, preventing further pupil constriction.  Another possibility could be a constriction or atrophy of the residual iris.  A scleral-sutured implant and an implantation in the capsular bag were both found to prevent the iris retraction.  The authors stated that the study group number was inadequate to allow statistical comparison of these different implantation methods.  As the use of artificial irises increases, one may expect more patients with iris retraction syndrome in the future

Frisina and colleagues (2021) stated that traumatic globe rupture can lead to aniridia with subsequent glare, light sensitivity and psychological discomfort.  These researchers reported the results of a sulcus implantation of a new IOL with artificial iris (Reper) in an eye affected by traumatic opening of a radial keratotomy incision with total iris extrusion and subluxated cataract.  The case entailed a 56-year old woman afflicted with aniridia and subluxated cataract in left eye secondary to a traumatic opening of 1 of 12 radial keratotomy; she underwent a Reper implantation with 3-point trans-scleral fixation.  The following parameters were collected at 1, 3 and 6 post-operative months: BCVA, IOP, central corneal thickness (CCT), simulated keratometry (Sim K), ECC and ACD.  Pupil spread function study was performed to examine the high-order aberrations and the quality of vision.  BCVA improved from light perception to 20/20 (Snellen fraction) at 6 months post-operatively.  No IOP post-operative peaks were detected; CCT was 520 μm at 6 months post-operatively.  Corneal topography showed regularization with symmetrical flattening of the central part and a residual peripheral curvature.  No significant reduction of ECC was detected; ACD was stable, superior to 3 mm at each time-point of follow-up.  Pupil spread function study highlighted that the quality of vision was the same in both eyes at the end of follow-up.  The authors concluded that Reper is a promising functional and cosmetic solution for the treatment of aphakia and aniridia

Son and associates (2020) reported the clinical outcomes following implantation of a small-aperture IOL and a partial aniridia ring in 3 patients with traumatic iris defects.  The corrected distance VA (CDVA), irregular astigmatism, and glare improved in all patients.  In 1 patient, the monocular defocus curve showed a VA of 0.30 logMAR or better from 1.0 to -1.5 D, and the halo size and intensity were 5 and 10 (on a scale from 0 to 100), respectively, and the glare size and intensity were 23 and 16 (on a scale from 0 to 100), respectively.  The authors concluded that the pin-hole effect of the small-aperture IOL helped considerably decreased irregular astigmatism and improved VA.  The partial aniridia implant also contributed to the reduction of the glare symptoms, while allowing a sufficient fundus assessment.  The combined implantation of the small-aperture IOL and the partial aniridia device, thus, presented an effective option for improvement of the visual symptoms in patients with traumatic iris defects.  Moreover, these researchers stated that further studies with larger sample size are needed to confirm its clinical efficacy.

Vasquez Quintero and associates (2021) carried out pre-clinical testing using optical design tools to simulate the optical quality of a smart artificial iris platform encapsulated in a scleral contact lens.  These tools allowed clinicians to generate aniridia eye models and examine different metrics of visual quality and retinal illumination based on the aperture of the artificial iris based on liquid crystals.  The OCT imaging technique was used to measure the geometry of the anterior segment in a patient with aniridia and, from these data, the eye model was generated with the Zemax optical design program and specific programs developed in Matlab.  Ocular aberrations were calculated and the visual function of the aniridia eye model was evaluated in three scenarios: without optical correction; with correction with a commercial scleral contact lens; and with correction with an optical lens; intelligent contact based on artificial iris.  Optical quality in patients with aniridia is limited by the magnitude of high-order aberrations.  Conventional scleral contact lens design accurately corrects for blur but is unable to compensate for high-order ocular aberrations, especially spherical aberrations.  The artificial iris-based smart contact lens design enables virtually all high-order aberrations to be compensated with active control of the pupillary diameter (activation of liquid crystal cells based on ambient lighting).  In addition to minimizing high-order aberrations, reducing the pupil size would increase the depth of focus.  This study showed by means of optical simulations the concept of an intelligent artificial iris platform encapsulated in a scleral contact lens and its possible application in patients with aniridia.  Furthermore, it allowed clinicians to anticipate possible visual results in clinical trials with healthy patients (after application of mydriatic agents) and in patients with aniridia.

In a retrospective case-series study, Ghaffari and colleagues (2021) reported complications of cosmetic artificial iris implantation and explantation outcomes.  Medical records of 12 patients (24 eyes) who presented to the authors after being implanted with cosmetic artificial irises elsewhere were reviewed.  Data collected included baseline demographics, presenting symptoms, examination findings, and management outcomes.  A total of 8 eyes had NewColorIris implants and 16 had BrightOcular implants.  The mean interval from cosmetic iris implantation to presentation was 61.7 ± 60.0 months.  The mean follow-up after explantation was 35.5 ± 38.1 months.  Complications at presentation included iris abnormalities (11 eyes, 45.8 %), elevated IOP (8 eyes, 33.3 %), corneal edema (6 eyes, 25 %), intra-ocular inflammation (5 eyes, 20.8 %), and cataract (4 eyes, 16.7 %).  Surgical interventions included cosmetic iris removal (19 eyes, 79.2 %), cataract extraction (7 eyes, 29.2 %), corneal transplantation (7 eyes, 29.2 %), and glaucoma surgery (4 eyes, 16.7 %).  Complications at the last follow-up examination included native iris defects (11 eyes, 45.8 %), persistent glaucoma (7 eyes, 29.2 %), cataract (5 eyes, 20.8 %), corneal edema (4 eyes, 16.7 %), and intra-ocular inflammation (2 eyes, 8.3 %).  The mean logarithm of the minimum angle of resolution was 0.56 ± 0.47 at presentation and 0.78 ± 0.88 at the last examination (p = 0.30).  The mean IOP was 22.7 ± 15.8 mm Hg at presentation and 13.4 ± 6.99 mm Hg at the last examination (p = 0.02).  The authors concluded that cosmetic iris implantation was associated with serious complications at the time of presentation, and adverse sequelae persisted for years after explantation.

In a retrospective study, Krishnan et al (2021) examined the outcome of various techniques for a custom-made iris prosthesis implantation as part of reconstructive anterior segment surgery following traumatic aniridia.  This trial was carried out for 6 eyes that received an artificial iris as secondary reconstructive measure for photophobia and unsatisfactory vision following initial globe repair.  Different implantation techniques were employed.  These included simple sulcus implantation, implantation of a composite (iris prosthesis with attached IOL) implant, and combinations with phacoemulsification, vitrectomy, and penetrating keratoplasty (PK).  In all cases, the artificial iris was implanted successfully.  In the follow-up period (1 to 48 months), post-operative complications included rhegmatogenous retinal detachment, prolonged intra-ocular inflammation, and corneal transplant decompensation due to graft rejection.  There was no case of secondary glaucoma.  Complications could be managed successfully.  All patients showed improved BCVA and were satisfied with functional and cosmetic results.  The authors concluded that the findings of this case-series study highlighted the different implantation techniques for reconstruction of the anterior segment following ocular trauma.  The versatility of the custom-made artificial iris accounted for a wide range of applications and the foldable material reduced the need for large incisions in the already traumatized eye.  Moreover, these investigators stated that due to the small number of cases presented, they could not draw any conclusions regarding the safety profile or effectiveness of the implant.

Jakob-Girbig et al (2021) described the use of the Ophtec artificial iris model C1 in patients with post-operative or traumatic aniridia/aphakia.  In 1 patient, it was combined with PK because of corneal scarring.  In both of the presented cases, improvement in VA and a satisfactory aesthetic result without any serious complications were observed; however, the short-term follow-up must be emphasized.  Thus, a final conclusion regarding possible complications could not yet be drawn.

Muth et al (2022) described a novel surgical technique of a combined implantation of an artificial iris and a scleral fixated IOL using flanged IOL haptics ("Yamane" technique).  The suturelessly implanted artificial iris-IOL-sandwich was stable with good functional as well as aesthetic results; however, this case showed a post-operative increase in IOP.  The authors concluded that this case showed that a visual as well as cosmetical rehabilitation appeared possible even after severe, penetrating ocular trauma with profound iris defects.  Moreover, these investigators stated that the sutureless IOL scleral fixation technique can also be used in combination with a sutureless artificial iris implantation.  They stated that further studies are needed to examine the long-term safety profile and rates of post-operative complications.  Aphakia was one of the key words listed in this study.

In a retrospective, consecutive, case-series study, Crawford et al (2022) evaluated repair of iris defects by endocapsular implantation of an artificial iris, in relation to visual outcomes, safety profile and patient satisfaction.  Medical records of patients implanted with an endocapsular artificial iris were reviewed and followed for minimum 3 months.  Patient characteristics, surgical management, clinical outcomes and subjective responses were recorded.  A total of 19 artificial irises were implanted in 18 patients.  Etiologies were iris melanotic lesion excision (73.7 %), ocular trauma (10.5 %), congenital aniridia (10.5 %) and Urrets-Zavalia syndrome (5.3 %).  During post-operative follow-up [14.1 ± 12.4 months (range of 3 to 59 months)], BCVA and IOP did not change significantly [BCVA, 0.23 logarithm of the minimum angle of resolution (logMAR) (20/32 Snellen) pre-operatively versus 0.18 logMAR post-operatively (20/25 Snellen) (Z = -0.222, p = 0.824); IOP, 15 mmHg pre-operatively versus 17 mmHg post-operatively (Z = 1.377, p = 0.1447)].  Mild or self-limiting complications included: elevated IOP (42.1 %), cystoid macular edema (CME; 15.8 %); persisting post-operative uveitis (15.8 %) and minor vaulting of the prosthesis (15.7 %).  Moderate or severe complications included significant vaulting of prosthesis that required surgical revision (5.3 %) and a single eye (5.3 %) with trabeculectomy and corneal graft failure; 94.4 % of patients were very satisfied with the cosmesis and would be highly likely to have the procedure again.  The authors concluded that endocapsular insertion of the custom-tailored artificial iris was an effective therapeutic option for the treatment of iris defects.  Severe post-operative complications were less common with this mode of implantation, although this must be interpreted in the context of innate differences in the study populations.  Furthermore, the percentage of patients experiencing vison loss in this trial was much lower than that reported in other studies.  These researchers stated that subjective data from this series suggested that artificial iris implantation attained high levels of patient satisfaction; they noted that the findings of this study suggested that endocapsular placement of a customized artificial iris was a safe and effective technique of iris reconstruction in suitable patients.  The main drawbacks of this study were its retrospective design, small sample size (n = 18 subjects) and heterogenous etiologies.

Romano et al (2022) stated that congenital aniridia is a rare, pan-ocular disorder with a main phenotypic characteristic of a partial or complete absence of the iris existing alongside other ocular morbidities such as cataract, keratopathy, optic nerve and foveal hypoplasia, and nystagmus.  The iris abnormality, however, often leads to symptoms such as photophobia, glare, and decreased VA, as well as cosmetic dissatisfaction.  Current management options for the iris deficit include colored iris contact lenses, corneal tattooing, and tinted contact lenses.  Symptoms arising from small iris defects can be resolved with surgical management using micro-tying suture techniques such as McCannel or Siepser.  Currently, larger iris defects can be treated with artificial iris implants.  New prosthetic options range from colored IOLs to flexible custom-made silicone iris implants.  With a range of therapeutic options available and given the challenges of multiple co-morbidities in aniridia, these investigators reviewed the literature relating to the use of artificial iris implants in congenital aniridia, with a focus on the different surgical implantation techniques, the clinical outcomes achieved, complications occurred, and risk of bias of the studies included.

These researchers highlighted the variability of iris implantation outcomes in congenital aniridia.  Their objective was to identify which prosthesis exhibited the most favorable outcomes; however, this proved difficult, and conclusions drawn from results may not be truly representative, being possibly overly positive.  Each type of prosthesis and technique presented with several adverse complications, and despite being able to associate some with certain prostheses, most complications appeared across all devices seemingly at random.  The most prevalent complication was post-operative glaucoma secondary to iris device implantation.  The mechanisms behind this and other complications, however, are not fully understood.  These investigators stated that further research in mechanisms leading to the observed complications would be of great benefit.  Once an understanding is established, surgeons can work to prevent them to avoid multiple interventions and improve patient outcomes.  The authors noted that, ideally, the use of randomized-control groups alongside patients are needed; however, ethical issues of restricting a potentially beneficial treatment to some patients would need to be considered, and it may be difficult to find homogeneous study groups as many ocular co-morbidities exist in aniridia.  Although congenital aniridia is a rare disease, ideally large prospective randomized control trials (RCTs) would be needed to achieve an appropriate level of scientific evidence concerning the use, outcomes, and complications of artificial iris devices.  These researchers were aware that RCTs may be difficult in case of congenital aniridia in view of lack of homogeneous subjects; however, well-designed non-randomized studies (NRSs) may provide good clinical practice evidence.  One issue is that the current literature, despite being composed of NRSs, suffered from high risk of bias, as shown with the ROBINS-tool.  Another important issue was the lack of outcome measures specific for aniridia, where the patient may benefit from interventions despite a lack of objective improvement in VA; more research is needed on the optimal time to implant the prosthetic iris device.  Furthermore, these investigators stated that it is important that surgeons and patients both understand the risk/benefit scenario before the decision to implant an artificial iris implantation is made, keeping in mind the limited scientific literature on this topic and the limitations and risks of bias within the individual studies.

In a case report, Watanabe and Kobayakawa (2023) described an approach for managing acquired aniridia induced by intra-operative floppy iris syndrome (IFIS) during cataract surgery.  The case entailed an 81-year-old man with right blurred vision and photophobia symptoms who was treated for extensive iris defects due to cataract surgery aniridia.  The retained iris for the patient was observed at the 5-10 o'clock position, with the IOL inside the capsular bag.  Although the aniridia symptoms were successfully addressed by the implantation of a foldable artificial iris, the procedure subsequently caused endothelial damage.  The authors concluded that this case report provided 2 main observations to the field of ophthalmic surgery.  First, the foldable artificial iris may be a potential approach that can be used for managing acquired aniridia.  Second, although the foldable artificial iris can help provide good visual function and cosmetic results, further improvements to the insertion technique are still needed.  Moreover, these researchers stated that although this technique aid in improving the blurred vision and photophobia symptoms in this case, a long-term follow-up of the patient is needed.

Artificial Iris for Anterior Segment Reconstruction

In a retrospective, case-series, pilot study, Ang and Tan (2022) described a surgical approach that entailed anterior segment reconstruction with CustomFlex Artificial Iris (CAI) followed by Descemet membrane endothelial keratoplasty (DMEK) in complex eyes with corneal decompensation.  This trial included eyes that underwent anterior segment restoration involving synechiolysis of peripheral anterior synechiae and excision of iris remnants; securing a well-fixated posterior chamber IOLs; and suture-fixated or capsular bag placement of CAI.  All eyes then underwent DMEK using a pull-through technique with the DMEK EndoGlide.  Main outcomes were successful anterior segment restoration and corneal clarity with CCT.  A total of 5 eyes of 5 patients (median age of 61 years, range of 27 to 69 years; 60 % women) underwent anterior segment reconstruction with CAI implantation (4 suture-fixated), followed by successful DMEK surgery (median of 2 months later, range of 1 to 5 months).  There were no major intra-operative complications or primary graft failure, with 1 peripheral graft detachment that underwent a successful re-bubble at 1 week.  All eyes had stable CAI implants and DMEK grafts remained clear at last follow-up with reduction in mean CCT (pre-operative: 658 ± 86 µm versus post-operative: 470 ± 33 µm, p = 0.005).  The authors concluded that the findings of this pilot study demonstrated a feasible approach of initial anterior segment reconstruction with CAI implantation, prior to DMEK, in eyes with significant anterior segment abnormalities such as iris damage or extensive peripheral anterior synechiae and corneal decompensation.

References

The above policy is based on the following references:

Artificial Retina

  1. Ahuja AK, Dorn JD, Caspi A, et al. Blind subjects implanted with the Argus II retinal prosthesis are able to improve performance in a spatial-motor task. Br J Ophthalmol. 2011;95(4):539-543.
  2. Alteheld N, Roessler G, Vobig M, et al. The retina implant--new approach to a visual prosthesis. Biomed Tech (Berl). 2004;49(4):99-103.
  3. Alteheld N, Roessler G, Walter P. Towards the bionic eye--the retina implant: Surgical, opthalmological and histopathological perspectives. Acta Neurochir Suppl. 2007;97(Pt 2):487-493.
  4. American Academy of Ophthalmology (AAO). Microelectronic retinal implants. AAO Rapid Clinical Report. San Francisco, CA: AAO; August 2000.
  5. Asher A, Segal WA, Baccus SA, et al. Image processing for a high-resolution optoelectronic retinal prosthesis. IEEE Trans Biomed Eng. 2007;54(6 Pt 1):993-1004.
  6. Barry MP, Dagnelie G; Argus II Study Group. Use of the Argus II retinal prosthesis to improve visual guidance of fine hand movements. Invest Ophthalmol Vis Sci. 2012;53(9):5095-5101.
  7. Breault Research Organization. Optoelectronic implants to treat visual diseases. Optics Report: Healthcare. Tucson, AZ: opticesreport.com; updated June 14, 2003. Available at: http://www.opticsreport.com/content/article.php?article_id=1007. Accessed July 11, 2005.
  8. Cheng DL, Greenberg PB, Borton DA. Advances in retinal prosthetic research: A systematic review of engineering and clinical characteristics of current prosthetic initiatives. Curr Eye Res. 2017;42(3):334-347.
  9. Chiang A, Haller JA. Vitreoretinal disease in the coming decade. Curr Opin Ophthalmol. 2010;21(3):197-202.
  10. Chow AY, Chow VY, Packo KH, et al. The artificial silicon retina microchip for the treatment of vision loss from retinitis pigmentosa. Arch Ophthalmol. 2004;122(4):460-469.
  11. Chuang AT, Margo CE, Greenberg PB. Retinal implants: A systematic review. Br J Ophthalmol. 2014;98(7):852-856.
  12. Dorn JD, Ahuja AK, Caspi A, et al; for the Argus II Study Group. The detection of motion by blind subjects with the epiretinal 60-electrode (Argus II) retinal prosthesis. Arch Ophthalmol. 2013;131(2):183-189.
  13. Duncan JL, Richards TP, Arditi A, et al. Improvements in vision-related quality of life in blind patients implanted with the Argus II Epiretinal Prosthesis. Clin Exp Optom. 2017;100(2):144-150.
  14. Endo T, Fujikado T, Hirota M, et al. Light localization with low-contrast targets in a patient implanted with a suprachoroidal-transretinal stimulation retinal prosthesis. Graefes Arch Clin Exp Ophthalmol. 2018;256(9):1723-1729.
  15. Farvardin M, Afarid M, Attarzadeh A, et al. The Argus-II retinal prosthesis implantation; from the global to local successful experience. Front Neurosci. 2018;12:584.
  16. Garcia S, Petrini K, Rubin GS, et al. Visual and non-visual navigation in blind patients with a retinal prosthesis. PLoS One. 2015;10(7):e0134369.
  17. Garg S. Retinitis pigmentosa: Treatment. UpToDate [online serial]. Waltham, MA: UpToDate; reviewed July 2013; May 2017.
  18. Gekeler F, Zrenner E, Bartz-Schmidt KU. Ocular electrical stimulation: Therapeutic application and active retinal implants for hereditary retinal degenerations. Ophthalmologe. 2015;112(9):712-719.
  19. Gekeler F, Zrenner E. Status of the subretinal implant project. An overview. Ophthalmologe. 2005;102(10):941-949.
  20. Golden JR, Erickson-Davis C, Cottaris NP, et al. Simulation of visual perception and learning with a retinal prosthesis. J Neural Eng. 2019;16(2):025003. 
  21. Ho AC, Humayun MS, Dorn JD, et al; Argus II Study Group. Long-term results from an epiretinal prosthesis to restore sight to the blind. Ophthalmology. 2015;122(8):1547-1554.
  22. Hornig R, Laube T, Walter P, et al. A method and technical equipment for an acute human trial to evaluate retinal implant technology. J Neural Eng. 2005;2(1):S129-S134.
  23. Humayun MS, Dorn JD, da Cruz L, et al; Argus II Study Group. Interim results from the international trial of Second Sight's visual prosthesis. Ophthalmology. 2012;119(4):779-788.
  24. Hung CC , Chiang Y-C, Lin Y-C, et al. Conception of a smart artificial retina based on a dual-mode organic sensing inverter. Adv Sci (Weinh). 2021;8(16):2100742.
  25. Kotecha A, Zhong J, Stewart D, da Cruz L. The Argus II prosthesis facilitates reaching and grasping tasks: A case series. BMC Ophthalmol. 2014;14:71.
  26. Lee PJ. ARMD, retinal electronic prosthesis and RPE transplantation. eMedicine Ophthalmology Topic 763. Omaha, NE: eMedicine.com; updated October 4, 2004.
  27. Luo YH, da Cruz L. A review and update on the current status of retinal prostheses (bionic eye). Br Med Bull. 2014;109:31-44.
  28. Luo YH, da Cruz L. The Argus(®) II retinal prosthesis system. Prog Retin Eye Res. 2016;50:89-107.
  29. Mokwa W, Goertz M, Koch C, et al. Intraocular epiretinal prosthesis to restore vision in blind humans. Conf Proc IEEE Eng Med Biol Soc. 2008;2008:5790-5793.
  30. Mokwa W. An implantable microsystem as a vision prosthesis. Med Device Technol. 2007;18(6):20, 22-23.
  31. Optobionics Corporation. ASR® device [website]. Naperville, IL: Optobionics; updated March 11, 2004. Available at: http://www.optobionics.com. Accessed July 11, 2005.
  32. Pei ZJ, Gao GX, Hao B, et al. A cascade model of information processing and encoding for retinal prosthesis. Neural Regen Res. 2016;11(4):646-651.
  33. Rizzo S, Belting C, Cinelli L, et al. The Argus II Retinal Prosthesis: 12-month outcomes from a single-study center. Am J Ophthalmol. 2014;157(6):1282-1290.
  34. Roessler G, Laube T, Brockmann C, et al. Implantation and explantation of a wireless epiretinal retina implant device: Observations during the EPIRET3 prospective clinical trial. Invest Ophthalmol Vis Sci. 2009;50(6):3003-3008.
  35. Sabbah N, Authie CN, Sanda N, et al. Importance of eye position on spatial localization in blind subjects wearing an Argus II retinal prosthesis. Invest Ophthalmol Vis Sci. 2014;55(12):8259-8266.
  36. Second Sight Medical Products. Argus™ II Retinal Stimulation System Feasibility Protocol. ClinicalTrials.gov. Identifier NCT00407602. Bethesda, MD: National Institutes of Health; updated August 28, 2008.
  37. Second Sight Medical Products. Feasibility Study of a Chronic Retinal Stimulator in Retinitis Pigmentosa. ClinicalTrials.gov. Identifier NCT00279500. Bethesda, MD: National Institutes of Health; updated January 8, 2007.
  38. Seitz IP, Achberger K, Liebau S, Fischer MD. Stem cells for retina replacement. Klin Monbl Augenheilkd. 2016;233(12):1350-1356.
  39. Stronks HC, Dagnelie G. The functional performance of the Argus II retinal prosthesis. Expert Rev Med Devices. 2014;11(1):23-30.
  40. U.S. Food and Drug Administration (FDA). FDA approves first retinal implant for adults with rare genetic eye disease. FDA News. Silver Spring, MD: FDA; February 14, 2013.
  41. Vandepeer M. Technology Brief: Argus II Retinal Prosthesis System for peripheral retinal degeneration. Health Policy Advisory Committee on Technology (HealthPACT). Australian Safety and Efficacy Register of New Interventional Procedures – Surgical (ASERNIP-S). Herston, QLD: Queensland Department of Health; November 2013.
  42. Viola MV, Patrinos AA. A neuroprosthesis for restoring sight. Acta Neurochir Suppl. 2007;97(Pt 2):481-486.  
  43. Weiland JD, Cho AK, Humayun MS. Retinal prostheses: Current clinical results and future needs. Ophthalmology. 2011;118(11):2227-2237.
  44. Weiland JD, Humayun MS. Retinal prosthesis. IEEE Trans Biomed Eng. 2014;61(5):1412-1424.
  45. Weiland JD, Liu W, Humayun MS. Retinal prosthesis. Annu Rev Biomed Eng. 2005;7:361-401.

Artificial Iris

  1. Ang M, Tan D. Anterior segment reconstruction with artificial iris and Descemet membrane endothelial keratoplasty: A staged surgical approach. Br J Ophthalmol. 2022;106(7):908-913.
  2. Clinical Research Consultants, Inc. CustomFlex™ Artificial Iris. Summary of Safety and Effectiveness Data. Premarket Approval Application (PMA) Number: P170039. Silver Spring, MD: FDA; May 30, 2018. 
  3. Crawford AZ, Freundlich SEN, Lim J, McGhee CNJ. Endocapsular artificial iris implantation for iris defects: Reducing symptoms, restoring visual function and improving cosmesis. Clin Exp Ophthalmol. 2022;50(5):490-499.
  4. Frisina R, De Biasi CS, Londei D,  et al. A new intraocular lens with artificial iris for treating a case of iris extrusion secondary to traumatic opening of a radial keratotomy. Eur J Ophthalmol. 2021;31(3):NP5-NP10.
  5. Ghaffari R, Aldave AJ, Al-Hashimi S, Miller KM. Complications of cosmetic artificial iris implantation and post explantation outcomes. Am J Ophthalmol. 2021;226:156-164.
  6. Jakob-Girbig J, Salewsky S, Meller D. Use of the Ophtec artificial iris model C1 in patients with aniridia/aphakia. Klin Monbl Augenheilkd. 2021;238(7):803-807.
  7. Krishnan VM, Todorova MG, Wiechens B, et al. The artificial iris -- analysis of various implantation techniques after ocular trauma. Indian J Ophthalmol. 2021;69(12):3526-3531.
  8. Mayer CS, Laubichler AE, Masyk M, et al. Residual iris retraction syndrome after artificial iris implantation. Am J Ophthalmol. 2019199:159-166. 
  9. Mostafa YS, Osman AA, Hassanein DH, et al. Iris reconstruction using artificial iris prosthesis for management of aniridia. Eur J Ophthalmol. 2018;28(1):103-107.
  10. Muth DR, Priglinger SG, Shajari M. Novel surgical technique of sutureless artificial iris and intraocular lens scleral fixation using Yamane technique. Am J Ophthalmol Case Rep. 2022;26:101502.
  11. Rickmann A, Szurman P, Januschowski K, et al. Long-term results after artificial iris implantation in patients with aniridia. Graefes Arch Clin Exp Ophthalmol. 2016;254(7):1419-1424.
  12. Romano D, Bremond-Gignac D, Barbany M, et al. Artificial iris implantation in congenital aniridia: A systematic review. Surv Ophthalmol. 2022 Nov 12 [Online ahead of print].
  13. Son H-S, Yildirim T, Khoramnia R, et al. Implantation of a small-aperture intraocular lens and a partial aniridia implant in eyes with traumatic iris defects. Am J Ophthalmol Case Rep. 2020;18:100673. 
  14. Vasquez Quintero A, Perez-Merino P, Fernandez Garcia AI, De Smet H. Smart contact lens: A promising therapeutic tool in aniridia.  Arch Soc Esp Oftalmol (Engl Ed). 2021;96(1):68-73.
  15. Watanabe N, Kobayakawa S. A case of foldable artificial iris implantation for treatment of postcataract surgery aniridia. Case Rep Ophthalmol. 2023;14(1):7-12.
  16. Weissbart SB, Ayres BD. Management of aniridia and iris defects: An update on iris prosthesis options. Curr Opin Ophthalmol. 2016;27(3):244-249.
  17. Yoeruek E, Bartz-Schmidt KU. A new knotless technique for combined transscleral fixation of artificial iris, posterior chamber intraocular lens, and penetrating keratoplasty. Eye (Lond). 2019;33(3):358-362.