38 research outputs found
Effects of Aging and Anatomic Location on Gene Expression in Human Retina
Objective: To determine the effects of age and topographic location on gene expression in human neural retina. Methods: Macular and peripheral neural retina RNA was isolated from human donor eyes for DNA microarray and quantitative RT-PCR analyses. Results: Total RNA integrity from human donors was preserved. Hierarchical clustering analysis demonstrates that the gene expression profiles of young, old, macula, and peripheral retina cluster into four distinct groups. Genes which are highly expressed in macular, peripheral, young, or old retina were identified, including inhibitors of Wnt Signaling Pathway (DKK1, FZD10, and SFRP2) which are preferably expressed in the periphery. Conclusion: The transcriptome of the human retina is affected by age and topographic location. Wnt pathway inhibitors in the periphery may maintain peripheral retinal cells in an undifferentiated state. Understanding the effects of age and topographic location on gene expression may lead to the development of new therapeutic interventions for age-related eye diseases
CUTS: A Fully Unsupervised Framework for Medical Image Segmentation
In this work we introduce CUTS (Contrastive and Unsupervised Training for
Segmentation) the first fully unsupervised deep learning framework for medical
image segmentation, facilitating the use of the vast majority of imaging data
that is not labeled or annotated. Segmenting medical images into regions of
interest is a critical task for facilitating both patient diagnoses and
quantitative research. A major limiting factor in this segmentation is the lack
of labeled data, as getting expert annotations for each new set of imaging data
or task can be expensive, labor intensive, and inconsistent across annotators:
thus, we utilize self-supervision based on pixel-centered patches from the
images themselves. Our unsupervised approach is based on a training objective
with both contrastive learning and autoencoding aspects. Previous contrastive
learning approaches for medical image segmentation have focused on image-level
contrastive training, rather than our intra-image patch-level approach or have
used this as a pre-training task where the network needed further supervised
training afterwards. By contrast, we build the first entirely unsupervised
framework that operates at the pixel-centered-patch level. Specifically, we add
novel augmentations, a patch reconstruction loss, and introduce a new pixel
clustering and identification framework. Our model achieves improved results on
several key medical imaging tasks, as verified by held-out expert annotations
on the task of segmenting geographic atrophy (GA) regions of images of the
retina
Long-Term Results from an Epiretinal Prosthesis to Restore Sight to the Blind
PurposeRetinitis pigmentosa (RP) is a group of inherited retinal degenerations leading to blindness due to photoreceptor loss. Retinitis pigmentosa is a rare disease, affecting only approximately 100 000 people in the United States. There is no cure and no approved medical therapy to slow or reverse RP. The purpose of this clinical trial was to evaluate the safety, reliability, and benefit of the Argus II Retinal Prosthesis System (Second Sight Medical Products, Inc, Sylmar, CA) in restoring some visual function to subjects completely blind from RP. We report clinical trial results at 1 and 3 years after implantation.DesignThe study is a multicenter, single-arm, prospective clinical trial.ParticipantsThere 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).MethodsThe 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.Main Outcome MeasuresThe primary outcome measures were safety (the number, seriousness, and relatedness of adverse events) and visual function, as measured by 3 computer-based, objective tests.ResultsA total of 29 of 30 subjects had functioning Argus II Systems implants 3 years after implantation. Eleven subjects experienced a total of 23 serious device- or surgery-related adverse events. 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.ConclusionsThe 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. Earlier results from this trial were used to gain approval of the Argus II by the Food and Drug Administration and a CE mark in Europe. The Argus II System is the first and only retinal implant to have both approvals
Subretinal Drusenoid Deposit Formation: Insights From Turing Patterns
PurposeThe purpose of this study was to demonstrate that the organized formation of subretinal drusenoid deposits (SDDs) may be a Turing pattern.MethodsA Java-based computational model of an inferred reaction-diffusion system using paired partial differential equations was used to create topographic images. Reaction kinetics were varied to illustrate a spectrum of pattern development, which were then compared to dot-like, reticular, and confluent SDD patterns observed clinically.ResultsA reaction-diffusion system using two agents, one an "activator" that increases its own production, and the other an "inhibitor" that decreases the activator's production, can create patterns that match the spectrum of topographic appearance of organized SDD. By varying a single parameter, the strength of the activator, the full spectrum of clinically observed SDD patterns can be generated. A new pattern, confluence with holes, is predicted and identified in one case example.ConclusionsThe formation of clinically significant SDD and its different patterns can be explained using Turing patterns obtained by simulating a two-component reaction-diffusion system.Translational relevanceThis model may be able to guide future risk stratification for patients with SDD, and provide mechanistic insights into the cause of the disease
A hierarchical Bayesian entry time realignment method to study the long-term natural history of diseases
A major question in clinical science is how to study the natural course of a chronic disease from inception to end, which is challenging because it is impractical to follow patients over decades. Here, we developed BETR (Bayesian entry time realignment), a hierarchical Bayesian method for investigating the long-term natural history of diseases using data from patients followed over short durations. A simulation study shows that BETR outperforms an existing method that ignores patient-level variation in progression rates. BETR, when combined with a common Bayesian model comparison tool, can identify the correct disease progression function nearly 100% of the time, with high accuracy in estimating the individual disease durations and progression rates. Application of BETR in patients with geographic atrophy, a disease with a known natural history model, shows that it can identify the correct disease progression model. Applying BETR in patients with Huntington's disease demonstrates that the progression of motor symptoms follows a second order function over approximately 20 years
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An In Silica Model for RPE Loss Patterns in Choroideremia
PurposeTo use empirical data to develop a model of cell loss in choroideremia that predicts the known exponential rate of RPE loss and central, scalloped preservation pattern seen in this disease.MethodsA computational model of RPE loss was created in Python 3.7, which constructed an array of RPE cells clusters, binarized as either live or atrophic. Two rules were applied to this model: the background effect gave each cell a chance of dying defined by a background function, and the neighbor effect increased the chance of RPE cell death if a neighbor were dead. The known anatomic distribution of rods, RPE, choriocapillaris density, amacrine, ganglion, and cone cells were derived from the literature and applied to this model. Atrophy growth rates were measured over arbitrary time units and fit to the known exponential decay model. The main outcome measures: included topography of atrophy over time and fit of simulated residual RPE area to exponential decay.ResultsA background effect alone can simulate exponential decay, but does not simulate the central island preservation seen in choroideremia. An additive neighbor effect alone does not simulate exponential decay. When the neighbor effect multiplies the background effect using the rod density function, our model follows an exponential decay, similar to previous observations. Also, our model predicts a residual island of RPE that resembles the topographic distribution of residual RPE seen in choroideremia.ConclusionsThe pattern of RPE loss in choroideremia can be predicted by applying simple rules. The RPE preservation pattern typically seen in choroideremia may be related to the underlying pattern of rod density. Further studies are needed to validate these findings
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Familial idiopathic macular hole
To report macular hole formation among siblings within four families.
Observational case series.
Four families were identified who had macular holes among siblings from within three multiphysician tertiary-care referral retina practices.
In the first family, two sisters in their seventh decade developed Stage 2 macular holes requiring surgical intervention; two male siblings were unaffected. In a second family, three of four siblings were affected, including one brother with a Stage 4 macular hole, one sister with a Stage 3 macular hole, and a third sister with a lamellar macular hole. In a third family, two siblings (one man, one woman) developed macular holes within 1 year of each other. Three years later, the male sibling developed a macular hole in the fellow eye. In the last family, twin sisters developed macular holes (unilateral in one sister, bilateral in the other), and their deceased father may also have had bilateral macular holes.
The occurrence of macular holes in these four sets of siblings suggests a possible genetic component in the formation of macular holes in these individuals
Topographic Variation of Retinal Vascular Density in Normal Eyes Using Optical Coherence Tomography Angiography
PurposeTo establish a continuous topography of retinal vessel density in normal eyes using optical coherence tomography angiography (OCTA).MethodsA retrospective chart review was performed, and 8-mm × 8-mm OCTA images from 22 normal eyes were analyzed. Vessel density was plotted as a continuous function of distance from the foveal center (radial vessel density) and directional meridians (directional vessel density) for the superficial capillary plexus and deep capillary plexus.ResultsContinuous radial and directional vessel density plots for the superficial and deep capillary plexus were generated. Radial vessel density analysis revealed transition points at 657 microns (95% confidence interval [CI], 619-696) and 950 microns (95% CI, 903-997) from the foveal center for the superficial plexus and deep plexus, respectively. Directional vessel density analysis demonstrated significant vessel density variations in these vascular layers and provided greater detail compared to traditional quadrant analysis.ConclusionsThere are significant topographic variations of retinal vessel density in normal eyes. Continuous vessel density analysis offers greater sensitivity in detecting topographic vessel density changes compared to traditional methods of analysis.Translational relevanceThis study establishes a normative continuous vessel density topography that may help elucidate the role of the vascular bed in different chorioretinal diseases