285 research outputs found

    Zapping the Retina - Understanding electrical responsiveness and electrical desensitization in mouse retinal ganglion cells

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    The field of science and technology has come a long way since the famous 70’s science fiction series “The Six Million Dollar Man,” where a disabled pilot was transformed into a bionic superhero after receiving artificial implants. What was indeed once a science fiction has now turned into a science fact with the development of various electronic devices interfacing the human neurons in the brain, retina, and limbs. One such advancement was the development of retinal implants. Over the past two decades, the field of retinal prosthetics has made significant advancement in restoring functional vision in patients blinded by diseases such as Retinitis pigmentosa (RP) and Age-related macular degeneration (AMD). RP and AMD are the two leading cause of degenerative blindness. While there is still no definitive cure for either of these diseases, various treatment strategies are currently being explored. Of the various options, the most successful one has been the retinal implants. Retinal implants are small microelectrode or photodiode arrays, which are implanted in the eye of a patient, to stimulate the degenerating retina electrically. They are broadly classified into three types depending on the placement ̶ epiretinal (close proximity to retinal ganglion cells, RGCs) , subretinal (close proximity to bipolar cells, BP) and suprachoroidal (close proximity to choroid). While the ongoing human trials have shown promising results, there remains a considerable variability among patients concerning the quality of visual percepts which limits the working potential of these implants. One such limitation often reported by the implanted patients is “ fading” of visual percepts. Fading refers to the limited ability to elicit temporally stable visual percepts. While, this is not a primary concern for epiretinal implants , it is often observed in subretinal and suprachoroidal implants which use the remaining retinal network to control the temporal spiking pattern of the ganglion cells. The neural correlate of fading is often referred to as “electrical desensitization”, which is the reduction of ganglion cell responses to repetitive electrical stimulation . While much is known about the temporal component of desensitization ( time constant, τ), the spatial aspects (space constant, λ) has not been well characterized. Further, how both these aspects interact to generate spiking responses, remains poorly understood. These crucial questions formed the critical components of my thesis. To address these questions, we stimulated the retinal network electrically, with voltage and current pulses and recorded the corresponding spiking activity using the microelectrode arrays (MEAs). While addressing the primary question of my thesis, we were able to address few idiosyncrasies which has currently stymied the field of retinal prosthetics. At a conceptual level, we have developed an experimental and analysis framework by which one can identify the single stimulus that will activate the most ganglion cells (Chapter 2, Part 1). This stimulus is optimal for ‘blind’ experiments where the specific response properties of each cell are unknown. Furthermore, we attempted to understand the correspondence between the electrical response patterns and visual response types (Chapter 2, Part2). In Chapter 3, we sought to understand better how the visual responses parameters change during ongoing electrical stimulation. We demonstrated that apart from the adaptation occurring due to visual stimulation and invitro experimental conditions, the electrical stimulation alters the RGC visual responses, suggesting the requirement for stimulation-induced changes to be incorporated in the designing of stimulation paradigms for the implant. Finally addressing the primary question (Chapter 4) of my thesis with which we started, we were able to demonstrate, that the electrical desensitization requires the interaction of both time and distance and is not a global phenomenon of the retina. In the final chapter (Chapter 5) we summarize the results of the thesis, discuss the key outcomes and its relevance to the prosthetic field and other vision restoration strategies and the potential future directions of this research. Therefore, in future, to improve the efficacy of retinal prostheses and patient outcomes, it is crucial to have an in-depth understanding of the responsiveness of the retinal circuitry to electrical stimulation

    Optimal electrical activation of retinal ganglion cells

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    Retinal prostheses are emerging as a viable therapy option for those blinded by degenerative eye conditions that destroy the photoreceptors of the retina but spare the retinal ganglion cells (RGCs). My research sought to address the issue of how a retinal prosthesis might best activate these cells by way of electrical stimulation. Whole-cell patch clamp recordings were made in explanted retinal wholemount preparations from normally-sighted rats. Stimulating electrodes were fabricated from nitrogen-doped ultra-nanocrystalline diamond (N-UNCD) and placed on the epiretinal surface, adjacent to the cell soma. Electrical stimuli were delivered against a distant monopolar return electrode. Using rectangular, biphasic constant current waveforms as employed by modern retinal prostheses, I examined which waveform parameters had the greatest effect on RGC activation thresholds. In a second set of experiments intracellular current injection was employed to assess the effectiveness of sinusoidal current waveforms in selectively activating different RGC subsets. These recordings were also used to validate a biophysical model of RGC activation. Where possible, recorded cells were identified and classified based on 3D confocal reconstruction of their morphology. Electrodes fabricated from N-UNCD were able to electrically activate RGCs while remaining well within the electrochemical limits of the material. They were found to exhibit high electrochemical stability and were resistant to morphological and electrochemical changes over one week of continuous pulsing at charge injection limits. Retinal ganglion cells invariably favoured cathodic-first biphasic current pulses of short first-phase duration, with a small interphase interval. The majority of cells (63\%) were most sensitive to a highly asymmetric waveform: a short-cathodic phase followed by a longer duration, lower amplitude anodic phase. Using the optimal interphase interval led to median charge savings of 14\% compared to the charge required in the absence of any inter-phase interval. Optimising phase duration resulted in median charge savings of 22\%. All RGCs became desensitised to repetitive electrical stimulation. The efficacy of a given stimulus delivered repeatedly decreased after the first stimulus, stabilising at a lower efficacy by the thirtieth pulse. This asymptotic efficacy decreased with increasing stimulus frequency. Cells with smaller somas and dendritic fields were better able to sustain repetitive activation at high frequency. Intracellular sinusoidal stimulation was used to demonstrate that certain RGC subsets, defined on the basis of morphological type, stratification, and size, were more responsive to high frequency stimulation. Simulated RGC responses were validated by experimental data, which confirmed that ON cell responses were heavily suppressed by stimulus frequencies of 20 Hz and higher. OFF cells, on the other hand, were able to sustain repetitive activation over all tested frequencies. Additional simulations suggest this difference may be plausibly attributed to the presence of low-voltage-activated calcium channels in OFF but not ON RGCs. The results of my work demonstrate that (a) N-UNCD is a suitable material for retinal prosthesis applications; (b) a careful choice of electrical waveform parameters can significantly improve prosthesis efficacy; and (c) it may be possible to bias neural activation for certain RGC populations by varying the frequency of stimulation

    Photovoltaic restoration of sight with high visual acuity

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    Patients with retinal degeneration lose sight due to the gradual demise of photoreceptors. Electrical stimulation of surviving retinal neurons provides an alternative route for the delivery of visual information. We demonstrate that subretinal implants with 70-Όm-wide photovoltaic pixels provide highly localized stimulation of retinal neurons in rats. The electrical receptive fields recorded in retinal ganglion cells were similar in size to the natural visual receptive fields. Similarly to normal vision, the retinal response to prosthetic stimulation exhibited flicker fusion at high frequencies, adaptation to static images and nonlinear spatial summation. In rats with retinal degeneration, these photovoltaic arrays elicited retinal responses with a spatial resolution of 64 ± 11 Όm, corresponding to half of the normal visual acuity in healthy rats. The ease of implantation of these wireless and modular arrays, combined with their high resolution, opens the door to the functional restoration of sight in patients blinded by retinal degeneration

    Stimulation of a Suprachoroidal Retinal Prosthesis Drives Cortical Responses in a Feline Model of Retinal Degeneration

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    PURPOSE. Retinal prostheses have emerged as a promising technology to restore vision in patients with severe photoreceptor degeneration. To better understand how neural degeneration affects the efficacy of electronic implants, we investigated the function of a suprachoroidal retinal implant in a feline model. METHODS. Unilateral retinal degeneration was induced in four adult felines by intravitreal injection of adenosine triphosphate (ATP). Twelve weeks post injection, animals received suprachoroidal electrode array implants in each eye, and responses to electrical stimulation were obtained using multiunit recordings from the visual cortex. Histologic measurements of neural and glial changes in the retina at the implant site were correlated with cortical thresholds from individual stimulating electrodes. RESULTS. Adenosine triphosphate-injected eyes displayed changes consistent with mid-to-late stage retinal degeneration and remodeling. A significant increase in electrical charge was required to induce a cortical response from stimulation of the degenerated retina compared to that in the fellow control eye. Spatial and temporal characteristics of the electrically evoked cortical responses were no different between eyes. Individual electrode thresholds varied in both the control and the ATP-injected eyes and were correlated with ganglion cell density. In ATP-injected eyes, cortical threshold was also independently correlated with an increase in the extent of retinal gliosis. CONCLUSIONS. These data suggest that even when ganglion cell density remains unaffected, glial changes in the retina following degeneration can influence the efficacy of suprachoroidal electrical stimulation. A better understanding of how glial change impacts retinal prosthesis function may help to further the optimization of retinal implants

    Elicitation of retinal neural circuitry with vision prosthetic devices

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    Vision prostheses currently under development by several research groups aim to restore functional sight to the profoundly blind suffering from retinal neural degenerative diseases. Human clinical trials in the last decade have demonstrated the ability of these devices to elicit simple percepts, such as bright spots of light. However, further improvements in implant perceptual efficacy will critically depend on improved understanding of the retinal neural mechanisms underlying the electrically evoked responses, and on how these mechanisms could be controlled artificially. In the first part of this thesis I quantitatively study, using a new statistical analysis technique, the temporal response properties of the retinal ganglion cells (RGCs) following electrical stimulation of the retina. I also demonstrate conclusively, for the first time, that small electrodes placed in the subretinal space could reliably elicit direct RGC spiking responses. In the second part of the thesis I investigate the mechanisms underlying the previously observed RGC response depression during repeated electrical stimulation of these cells. The experimental findings lead me to the development of a new stimulation method for preventing the response depression. The image processor is a crucial component of a vision prosthesis. It replaces some of the neural computations that occur in a healthy retina by converting visual stimuli into electrical stimuli. In the final part of the thesis I implement an image processor for a vision prosthesis. I show that such devices could be built with appropriate embedded hardware. Benchmark testing suggests that, depending on the complexity of the image processing strategies, care should be exercised in generalising the performance of algorithms developed on standard computers to these embedded devices

    Developing a new generation of neuro-prosthetic interfaces: structure-function correlates of viable retina-CNT biohybrids

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    PhD ThesisOne of the many challenges in the development of neural prosthetic devices is the choice of electrode material. Electrodes must be biocompatible, and at the same time, they must be able to sustain repetitive current injections in a highly corrosive physiological environment. We investigated the suitability of carbon nanotube (CNT) electrodes for retinal prosthetics by studying prolonged exposure to retinal tissue and repetitive electrical stimulation of retinal ganglion cells (RGCs). Experiments were performed on retinal wholemounts isolated from the Cone rod homeobox (CRX) knockout mouse, a model of Leber congenital amaurosis. Retinas were interfaced at the vitreo-retinal juncture with CNT assemblies and maintained in physiological conditions for up to three days to investigate any anatomical (immunohistochemistry and electron microscopy) and electrophysiological changes (multielectrode array stimulation and recordings; electrodes were made of CNTs or commercial titanium nitride). Anatomical characterisation of the inner retina, including RGCs, astrocytes and MĂŒller cells as well as cellular matrix and inner retinal vasculature, provide strong evidence of a gradual remodelling of the retina to incorporate CNT assemblies, with very little indication of an immune response. Prolonged electrophysiological recordings, performed over the course of three days, demonstrate a gradual increase in signal amplitudes, lowering of stimulation thresholds and an increase in cellular recruitment for RGCs interfaced with CNT electrodes, but not with titanium nitride electrodes. These results provide for the first time electrophysiological, ultrastructural and cellular evidence of the time-dependent formation of strong and viable bio-hybrids between the RGC layer and CNT arrays in intact retinas. We conclude that CNTs are a promising material for inclusion in retinal prosthetic devices

    Response of Mouse Visual Cortical Neurons to Electric Stimulation of the Retina

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    Retinal prostheses strive to restore vision to the blind by electrically stimulating the neurons that survive the disease process. Clinical effectiveness has been limited however, and much ongoing effort is devoted toward the development of improved stimulation strategies, especially ones that better replicate physiological patterns of neural signaling. Here, to better understand the potential effectiveness of different stimulation strategies, we explore the responses of neurons in the primary visual cortex to electric stimulation of the retina. A 16-channel implantable microprobe was used to record single unit activities in vivo from each layer of the mouse visual cortex. Layers were identified by electrode depth as well as spontaneous rate. Cell types were classified as excitatory or inhibitory based on their spike waveform and as ON, OFF, or ON-OFF based on the polarity of their light response. After classification, electric stimulation was delivered via a wire electrode placed on the surface of cornea (extraocularly) and responses were recorded from the cortex contralateral to the stimulated eye. Responses to electric stimulation were highly similar across cell types and layers. Responses (spike counts) increased as a function of the amplitude of stimulation, and although there was some variance across cells, the sensitivity to amplitude was largely similar across all cell types. Suppression of responses was observed for pulse rates ≄3 pulses per second (PPS) but did not originate in the retina as RGC responses remained stable to rates up to 5 PPS. Low-frequency sinusoids delivered to the retina replicated the out-of-phase responses that occur naturally in ON vs. OFF RGCs. Intriguingly, out-of-phase signaling persisted in V1 neurons, suggesting key aspects of neural signaling are preserved during transmission along visual pathways. Our results describe an approach to evaluate responses of cortical neurons to electric stimulation of the retina. By examining the responses of single cells, we were able to show that some retinal stimulation strategies can indeed better match the neural signaling patterns used by the healthy visual system. Because cortical signaling is better correlated to psychophysical percepts, the ability to evaluate which strategies produce physiological-like cortical responses may help to facilitate better clinical outcomes
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