Clinical Trial
doi: 10.1371/journal.pone.0115239. eCollection 2014.First-in-human trial of a novel suprachoroidal retinal prosthesis
Lauren N Ayton 1, Peter J Blamey 2, Robyn H Guymer 1, Chi D Luu 1, David A X Nayagam 3, Nicholas C Sinclair 4, Mohit N Shivdasani 2, Jonathan Yeoh 1, Mark F McCombe 1, Robert J Briggs 1, Nicholas L Opie 1, Joel Villalobos 4, Peter N Dimitrov 1, Mary Varsamidis 1, Matthew A Petoe 4, Chris D McCarthy 5, Janine G Walker 5, Nick Barnes 5, Anthony N Burkitt 6, Chris E Williams 4, Robert K Shepherd 2, Penelope J Allen 1; Bionic Vision Australia Research Consortium
Affiliations
- PMID:25521292
- PMCID: PMC4270734
- DOI: 10.1371/journal.pone.0115239
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Clinical Trial
First-in-human trial of a novel suprachoroidal retinal prosthesis
Lauren N Ayton et al. PLoS One..
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Abstract
Retinal visual prostheses ("bionic eyes") have the potential to restore vision to blind or profoundly vision-impaired patients. The medical bionic technology used to design, manufacture and implant such prostheses is still in its relative infancy, with various technologies and surgical approaches being evaluated. We hypothesised that a suprachoroidal implant location (between the sclera and choroid of the eye) would provide significant surgical and safety benefits for patients, allowing them to maintain preoperative residual vision as well as gaining prosthetic vision input from the device. This report details the first-in-human Phase 1 trial to investigate the use of retinal implants in the suprachoroidal space in three human subjects with end-stage retinitis pigmentosa. The success of the suprachoroidal surgical approach and its associated safety benefits, coupled with twelve-month post-operative efficacy data, holds promise for the field of vision restoration.
Trial registration: Clinicaltrials.govNCT01603576.
Conflict of interest statement
Figures
To date, clinical trials have been performed with devices in the A: epiretinal position , B: subretinal space and D: intrascleral space . Image modified with permission from Bionic Vision Australia.
The electrodes on the intraocular array (C) were numbered for analysis, with the black electrodes (21a to 21m) being ganged to provide an external ring for common ground and hexagonal stimulation parameter testing. Note electrodes 9, 17 and 19 were smaller (400 µm vs. 600 µm). The percutaneous connector protruded through the skin behind the ear (D), allowing direct connection to the neurostimulator via a connecting lead (E). The scleral incision was made 9 mm to 10 mm posteriorly from the sclero-corneal limbus.
The horizontal arrow on the infrared image indicates the direction of the OCT scan (A). The cross-sectional OCT image (B) shows the silicone and platinum electrode components of the array, the retina structure and choroidal vasculature, and the electrode to retina distance used for analysis (double-headed arrow). Scale bars = 200 µm.
Complete resolution of the hemorrhage occurred in this subject by 55 days post-operatively. Note the electrode array with individual electrodes can be seen more clearly over time as the blood clears in the temporal retina (arrow).
Each boxplot includes the maximum (upper whisker, excluding outliers), upper quartile (top of box), median (horizontal line in box), lower quartile (bottom of box) and minimum values (lower whisker). Open circles are outliers. The numbers represent the electrode location (see Fig. 2), and the horizontal lines on the graph of P3 represent single data points.
The leading edge of the array is marked with a white arrow in the 3-day images. The position of the fovea is marked with a white cross in the 6-month images.
This distance was relatively constant in P1, but increased up to two-fold in P2 and P3 over time. Note significant nystagmus in P3 made the measurements difficult, leading to greater variation in the values recorded. Outliers are identified by open circles, and the numbers represent the electrode location (see Fig. 2).
Additional scans were taken to monitor the percutaneous connector (not shown), which also stayed stable over this time period.
Impedances were measured with charge-balanced biphasic current pulses (pulse phase width: 25 µs; amplitude: 75 µA). The dotted lines represent the date of first stimulation. In P1 & P2, the impedances were stable over the implantation and stimulation period. Impedances measured in P3 decreased over the course of the implantation period. Outliers are identified by open circles, and the numbers represent the electrode location (see Fig. 2).
Table (C) shows the number of electrodes that were capable of eliciting a visual percept using the given stimulation parameters in each subject. PW = phase width, IPG = interphase gap, pps = pulses per second. Stimulus duration was 2 seconds in all cases.
Whiskers extend to minimum and maximum recorded thresholds and the box extents show inter-quartile range. The Lanczos2 vision processing performed significantly better than System Off (P = .01). Note that the visual acuity exceeded the 3.24 logMAR software limit in all trials with device off (floor effect).
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