View clinical trials related to Low Vision.
Filter by:The aims of this exploratory research project are to customize, deploy and evaluate the preliminary efficacy of a socially assistive robot as a novel approach to motivate and encourage optimal, long-term use of new magnification devices for reading in individuals with vision loss. The goals are to promote patient acceptance, adherence and skills reinforcement to achieve proficiency in the use of the magnifier, in order to attempt to reduce visual disability while performing important daily activities, such as reading tasks. This is a high priority given the increasing prevalence of low vision, paucity of low vision rehabilitation providers, and barriers related to access to care, such as transportation and geography, all of which motivate the development of this complementary approach for the provision of additional support at home by the socially assistive robot.
The successful application of magnification devices for reading and daily tasks is predicated on their correct use by individuals with low vision (LV). Barriers related to transportation, geography, and/or co-morbidities often limit LV patients' ability to attend several in-office training sessions as part of low vision rehabilitation (LVR) to optimize visual function with magnification devices. A promising solution is real-time videoconferencing to provide telerehabilitation, involving remotely delivered LVR services by a LVR provider in office to a patient at home. Telerehabilitation for LV appears to be feasible and acceptable by both patients and LVR providers, yet there are no published outcomes on the potential to improve patients' visual functioning. Another key issue in LVR is the need for an effective system to continually assess how patients are functioning at home. Ideally this would involve a non-invasive, efficient method to assess when magnifier device abandonment occurs, so that a timely telerehabilitation session can be initiated. Small Bluetooth low energy beacon sensors attached to the handles of magnifiers can collect real-time data regarding minute-to-minute environmental changes, which might serve as an indicator of magnifier use by LV patients at home. Specifically, the investigators propose to assess the potential for telerehabilitation to enhance visual function by providing remotely-delivered LVR training to use magnification devices. Following one in-office training session for new magnification device(s), the investigators aim to determine if there is additional gain in visual functioning by randomizing subjects to telerehabilitation or additional in-office LVR (active control). Participants will be assessed before and after two consecutive periods: (1) one month after a single LVR training session, followed by (2) up to three LVR sessions over a three month period either via telerehabilitation in the participants' homes or LVR in-office. The investigators will determine which patient characteristics and/or magnification devices are most likely to benefit from telerehabilitation. The investigators will also determine whether data from Bluetooth beacon sensors are valid indicators of hand-held magnifier device usage by LV patients at home. The study investigators will deploy Estimote Sticker beacon sensors to subjects randomized to telerehabilitation or additional in-office LVR during the same study period. It is anticipated that beacon sensors will measure significantly increased temperature and/or motion when placed on the part of the magnification device held by LV patients while performing daily activities. Beacon sensor data will determine if it is feasible to assess when magnification devices are used, and if the frequency of magnifier use changes following telerehabilitation or in-office LVR. This work will evaluate and refine the procedures for implementing these technologies for LVR, in order to develop future randomized controlled trial protocols. The investigators envision that telerehabilitation and beacon sensors could improve LV patient outcomes by providing follow-up LVR services in a more efficient and timely manner.
Data from 15 healthy subjects will be recorded in two testing sessions spread on two days, using three lens designs (A, B and C). Before the measuring days, each subject will undergo an extra fitting session of a large-diameter scleral contact lens on the dominant eye, assessed by an experienced practitioner. The fitting data will be used to custom-make the three lens designs for each subject, thus ensuring their comfort and safety during the days of the experiments. During the experiment days baseline measurements will be obtained before and after pupil dilation and contact lens wear. During the first testing session data from the lens design A (reference lens without artificial iris) will be recorded. During the second testing session data from the lens designs B and C (lenses with artificial iris with different transmittances) will be recorded. In each testing session, contrast sensitivity and visual acuity will be evaluated and non-invasive imaging measurements will be undertaken (optical coherence tomography and slit lamp). A specific questionnaire will be given to the subject to assess comfort, light sensitivity, the horizontal visual angle and overall experience of the scleral lens and in combination with a pair of sunglasses category 3-4.
The National Eye Institute estimated about 3 million people over age 40 in the US had low vision in 2010 and projects an increase to nearly 5 million in 2030 and 9 million in 2050. Current assistive technologies are a patchwork of mostly low-technology aids with limited capabilities that are often difficult to use, and are not widely adopted. This shortfall in capabilities of assistive technology often stems from lack of a user-centered design approach and is a critical barrier to improve the everyday activities of life (EDAL) and the quality of life (QOL) for individuals with low vision. An intuitive head mounted display (HMD) system on enhancing orientation and mobility (O&M) and crosswalk navigation, could improve independence, potentially decrease falls, and improve EDAL and QOL. The central hypothesis is that an electronic navigation system incorporating computer vision will enhance O&M for individuals with low vision. The goal is to develop and validate a smartHMD by incorporating advanced computer vision algorithms and flexible user interfaces that can be precisely tailored to an individual's O&M need. This project will address the specific question of mobility while the subject crosses a street at a signaled crosswalk. This is a dangerous and difficult task for visually impaired patients and a significant barrier to independent mobility.
The primary objective is to compare the effectiveness and adverse side-effects of the virtual bioptic telescope and virtual projection screen in a new head-mounted video-based low vision enhancement system (LVES) with a wide field of view to currently employed specifications for head-mounted video display low vision enhancement technology. Secondary objectives are to acquire qualitative information from patients to evaluate the functioning of the system, to optimize system features and operations, and to assess the value patients place on system features, functions, and operating parameters relative to those of current technology. Investigators will conduct a comparative effectiveness study to determine if the novel vision enhancing features of LVES 2 provide low vision patients with benefits superior to those provided by existing technology.
This project is working on orthoptic rehabilitation for low vision people. The aim of the project is to assess the interest and integration of this rehabilitation device used at home, in low-vision private practice and at the hospital. It leads to develop and evaluate an innovative device to integrate and adjust monitoring of patients according to their need and their progress, to create new interactions with the patient, enabling the orthoptist to stay in touch with his patient at home between rehabilitation sessions and to obtain a more fine and objective analysis of the exercises done by the patient. Using an eye tracker and a digital tactile screen with data uploads allows the practitioner to observe the progress objectively. It also leads the patient to a better understanding of his/her visual behavior and of the effects of rehabilitation. Therefore, it will be easier to adopt better strategies.
Age-related macular degeneration (AMD) is a condition affecting 20 to 25 million people worldwide. Symptoms of AMD includes difficulty in reading, recognizing faces and completing house work which may result in increased disability which in turn increase symptoms of depression and anxiety. Depression and anxiety could also be worsened by social isolation caused by AMD. Further, AMD causes high levels of emotional distress and reduced quality of life (QoL). Automatic Self Transcending Meditation (ASTM) - a standardized category of meditation - may help reduce stress, depression, anxiety, and may enhance QoL. Automatic Self Transcending Meditation (ASTM) is a class of meditation that helps quiet the mind and induces physiological and mental relaxation whilst the eyes are shut. It utilizes a specific sound value (mantra) to draw attention inward and permit the mind to experience a restful but alert state of consciousness. In the proposed research, the effects of ASTM on health related quality of Life (HRQoL), depression and anxiety in low-vision AMD patients will be studied. A single-center, single-blind longitudinal randomized controlled trial (RCT) will be conducted in London, ON. Patients with AMD (n = 140, 70 in each arm) will be randomized to ASTM plus treatment as usual (TAU) or TAU alone (control) arm. Data on routinely measured ophthalmic clinical variables, HRQoL, depression, and anxiety will be collected from both the arms. Statistical analysis will be conducted using STATA 15.0 to evaluate the effects of ASTM plus TAU compared to TAU alone on HRQoL, depression, and anxiety. Further, for each group - ASTM plus TAU and TAU alone - the investigators develop an association between HRQoL, depression, and anxiety with routinely measured clinical variables using mathematical models.
The purpose of this research is to collect preliminary data in preparation for conducting a randomized clinical trial to determine the relative effectiveness of vision rehabilitation in improving overall visual ability (primary aim) and reducing depression (secondary aim) in patients receiving anti-VEGF therapy for neovascular age-related macular degeneration integrated over time.
This study serves to test a previously evaluated falls prevention intervention recommended by the Centers for Disease Control and Prevention, entitled the Study of Accidental Falls in the Elderly (SAFE) Health Behavior and Exercise Intervention, to evaluate if the intervention is accessible to older adults with low vision receiving services from the Southeastern Blind Rehabilitation Center (SBRC). This study also serves to pilot a version of the SAFE intervention that has been adapted to be accessible for individuals with low vision at SBRC.
Low vision patients have difficulty acquiring sufficient visual information in a timely manner for the purpose of performing challenging daily tasks, such as traveling independently and safely through busy streets. The advance of virtual reality techniques has provided a potential platform for training low vision patients to use their remaining vision more efficiently, but the key issue is always whether the patient's visual experiences in a virtual world can be transferred to the real world. The proposed study is designed to provide definite answer to this question.